Pongrama Ramasoota | Molecular and Cellular Neuroscience | Best Researcher Award

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Prof. Dr. Pongrama Ramasoota | Molecular and Cellular Neuroscience | Best Researcher Award

Prof. Dr. Pongrama Ramasoota, Mahidol University, Thailand.

Dr. Pongrama Ramasoota is a distinguished professor and researcher specializing in antibody research and virology at the Centre of Excellence for Antibody Research (CEAR), Mahidol University, Thailand. With a strong academic foundation in veterinary medicine, public health, and microbiology, he has dedicated his career to developing therapeutic and diagnostic monoclonal antibodies against viruses such as Dengue, Rabies, Foot and Mouth Disease, and Influenza. His contributions extend beyond infectious disease research, as he has also explored anti-aging supplements for humans and pets. Recognized with numerous national and international awards, his research has significantly impacted medical biotechnology, earning him a reputation as a leading scientist in his field.

 

Profile

Scopus

 

🎓 Early Academic Pursuits

Pongrama Ramasoota’s journey into the world of microbiology and antibody research began with a solid foundation in veterinary medicine. He earned his Doctor of Veterinary Medicine from Kasetsart University, where his fascination with infectious diseases and immunology took root. His academic pursuits led him to Mahidol University, where he obtained a Master of Public Health, further broadening his expertise in disease prevention and control. Driven by a passion for scientific exploration, he pursued a Master of Science and Ph.D. in Microbiology at the prestigious Swedish University of Agricultural Sciences in Uppsala, Sweden. These formative years were instrumental in shaping his career as a leading researcher in antibody development and disease management.

đŸ„ Professional Endeavors

As a distinguished professor at the Centre of Excellence for Antibody Research (CEAR) within the Faculty of Tropical Medicine, Mahidol University, Dr. Ramasoota has dedicated his career to advancing the field of immunotherapy. His research primarily focuses on developing neutralizing monoclonal antibodies to combat viral threats such as Dengue and Rabies. Over the years, he has led groundbreaking projects aimed at creating effective therapeutic and diagnostic solutions. His expertise has also extended beyond academia, as he collaborates with industry leaders to translate research into practical applications that benefit global health.

🩠 Contributions and Research Focus

Dr. Ramasoota’s contributions to medical research are vast and impactful. His work on neutralizing human monoclonal antibodies against Dengue and Rabies viruses has paved the way for potential life-saving treatments. His research extends to diagnostic monoclonal antibodies for detecting Foot and Mouth Disease Virus (FMDV) and Influenza, significantly enhancing disease surveillance. Beyond infectious diseases, he has also ventured into anti-aging research, developing natural supplements to promote longevity in both humans and pets. His relentless pursuit of innovation continues to drive advancements in virology, immunotherapy, and biotechnology.

🏆 Accolades and Recognition

Dr. Ramasoota’s contributions to science have been recognized with numerous prestigious awards. He was honored as Thailand’s Outstanding Researcher in 2020 and named Thailand’s Outstanding Veterinarian in 2016. His innovative work earned him multiple Outstanding Research and Invention Awards from the National Research Council of Thailand between 2008 and 2016. He has also received international recognition, including a gold medal from the 2014 Taipei Invention & Techno Mart and awards from the Korea Invention Association and the International Federation of Inventors’ Associations. These accolades underscore his influence as a pioneer in antibody research and biotechnology.

🌍 Impact and Influence

With an H-index of 18 and over 1,038 citations on Scopus, Dr. Ramasoota’s research has significantly influenced the scientific community. His findings have been instrumental in shaping new treatment strategies for viral diseases, providing hope for better therapeutic interventions. Collaborating with industry leaders such as Advy Chemical (India) and Thai-Naoka (Thailand), he has helped bridge the gap between research and real-world applications. His contributions to diagnostic tools and monoclonal antibody therapies continue to shape the future of virology and medical biotechnology.

📚 Legacy and Future Contributions

Beyond his research endeavors, Dr. Ramasoota has authored books that highlight his expertise in environmental management and anti-aging technologies. His book Hallmarks of Aging, Technology and Innovation for Anti-Aging explores groundbreaking advancements in longevity research, demonstrating his commitment to improving human health across various dimensions. As he continues to innovate, his legacy as a leading researcher in antibody development and viral immunotherapy will inspire future generations of scientists. His ongoing efforts to combat infectious diseases and promote healthier aging promise a lasting impact on global health and biotechnology.

Publication

  1. Title: Development of novel canine phage display-derived neutralizing monoclonal antibody fragments against rabies virus from immunized dogs
    Authors: A. Chorpunkul, U. Boonyuen, K. Limkittikul, P. Lekcharoensuk, P. Ramasoota
    Year: 2024

 

  1. Title: Characterization of Vibrio parahaemolyticus isolated from clinical specimens and oysters in Thailand
    Authors: N. Tewawong, S. Kowaboot, S. Kengkarn, P. Ramasoota, O. Suthienkul
    Year: 2024

 

  1. Title: Nicotiana benthamiana as a potential source for producing anti-dengue virus D54 neutralizing therapeutic antibody
    Authors: S. Krittanai, K. Rattanapisit, C.J.I. Bulaon, R. Strasser, W. Phoolcharoen
    Year: 2024

 

  1. Title: Associations of effort-reward imbalance at work and quality of life among workers after stroke: a one-year longitudinal study in Thailand
    Authors: S. Naknoi, J. Li, P. Ramasoota, N. Soonthornworasiri, O. Kaewboonchoo
    Year: 2023

 

  1. Title: Potential Protective Effect of Dengue NS1 Human Monoclonal Antibodies against Dengue and Zika Virus Infections
    Authors: R. Sootichote, W. Puangmanee, S. Benjathummarak, P. Ramasoota, P. Pitaksajjakul
    Year: 2023

 

  1. Title: A replication competent luciferase-secreting DENV2 reporter for sero-epidemiological surveillance of neutralizing and enhancing antibodies
    Authors: K. Saipin, B.K. Thaisomboonsuk, B. Siridechadilok, N. Sittisombut, J. Junjhon
    Year: 2022

 

  1. Title: Spread of a Novel Indian Ocean Lineage Carrying E1‐K211E/E2‐V264A of Chikungunya Virus East/Central/South African Genotype across the Indian Subcontinent, Southeast Asia, and Eastern Africa
    Authors: J. Phadungsombat, H.A. Imad, E.E. Nakayama, W. Piyaphanee, T. Shioda
    Year: 2022

 

🎯 Conclusion

Dr. Ramasoota’s work has not only advanced scientific knowledge but also contributed to real-world solutions in disease treatment and diagnostics. His collaborations with industries and commitment to innovation ensure that his research continues to benefit global health. As he continues to push the boundaries of antibody research and anti-aging science, his legacy will inspire future generations of scientists, leaving a lasting impact on virology, immunotherapy, and biotechnology.

 

Kiran Solingapuram Sai | Neuroimaging | Best Researcher Award

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Dr. Kiran Solingapuram Sai | Neuroimaging | Best Researcher Award

Dr. Kiran Solingapuram Sai, Wake Forest School of Medicine, United States.

Dr. Kiran K. Solingapuram Sai, PhD, is an Associate Professor with tenure in the Department of Radiology at Wake Forest School of Medicine. He holds a Ph.D. in Organic Chemistry from Northern Illinois University and has extensive research experience in radiopharmaceutical chemistry. His postdoctoral training at Washington University’s Mallinckrodt Institute of Radiology focused on radiotracer development.

Profile

Orcid

 

✹ Early Academic Pursuits

Dr. Kiran K. Solingapuram Sai embarked on his academic journey with a strong foundation in chemistry, earning a Bachelor of Science degree in Chemistry, Biochemistry, and Microbiology from Osmania University, Hyderabad, India, in 2001. His passion for organic chemistry led him to pursue a Master of Science in the same field at Osmania University, where he honed his expertise in chemical synthesis and molecular interactions. Determined to explore the depths of organic chemistry, he pursued his Ph.D. at Northern Illinois University, DeKalb, IL, under the mentorship of Dr. Douglas A. Klumpp. During this period, his research focused on synthetic methodologies and organic reaction mechanisms, paving the way for his future contributions to medicinal and radiopharmaceutical chemistry.

🌐 Professional Endeavors

Dr. Sai’s professional journey commenced with a prestigious postdoctoral research associate position at the Mallinckrodt Institute of Radiology at Washington University in St. Louis, MO, where he worked under the guidance of Dr. Robert H. Mach. During his tenure from 2010 to 2013, he delved into the complexities of radiochemistry, developing novel radiotracers and exploring their applications in medical imaging. This experience laid the groundwork for his career in radiopharmaceutical sciences. In 2014, he joined Wake Forest School of Medicine as a Research Instructor and Chief Radiochemist, marking the beginning of his significant contributions to translational imaging and radiopharmaceutical production.

⚛ Contributions and Research Focus

At Wake Forest School of Medicine, Dr. Sai played a pivotal role in the Department of Radiology and the Clinical Translational Science Institute (CTSI). He specialized in managing clinical and research-based radiopharmaceutical production at the Wake Forest PET Research Center. As a cyclotron manager and coordinator, he oversaw the synthesis and quality control of radiotracers essential for PET imaging. His expertise extended to the development and implementation of cGMP-approved protocols for C-11 and F-18 radiopharmaceutical production, ensuring the highest standards of safety and efficacy. His research focuses on advancing PET imaging techniques, exploring new radiotracers for diagnostic and therapeutic applications, and improving imaging biomarker development.

🏆 Accolades and Recognition

Dr. Sai’s dedication to radiochemistry and molecular imaging has earned him recognition in the scientific community. His work has been instrumental in developing radiopharmaceuticals for neurological and oncological imaging, contributing significantly to early disease detection and targeted therapy. His contributions have been acknowledged through numerous research grants, collaborative projects, and publications in high-impact scientific journals. His commitment to excellence and innovation has positioned him as a leading figure in the field of radiopharmaceutical sciences.

🔬 Impact and Influence

Beyond his research and technical expertise, Dr. Sai has mentored budding scientists and researchers in the field of radiochemistry and imaging sciences. His guidance has helped shape the next generation of radiopharmaceutical experts, fostering a culture of innovation and scientific curiosity. His role in translational imaging programs has bridged the gap between basic research and clinical applications, directly impacting patient care by improving diagnostic imaging techniques.

💡 Legacy and Future Contributions

Dr. Sai’s work continues to inspire advancements in molecular imaging and radiopharmaceutical development. As an Associate Professor with tenure at Wake Forest School of Medicine, he remains dedicated to pushing the boundaries of radiochemistry, developing cutting-edge imaging agents, and enhancing the precision of diagnostic medicine. His legacy in the field is defined by his unwavering commitment to scientific discovery, translational research, and the continuous pursuit of excellence in radiopharmaceutical sciences.Dr. Kiran K. Solingapuram Sai’s contributions to the field of radiopharmaceutical chemistry stand as a testament to his dedication, innovation, and impact on medical imaging and healthcare. His journey from a passionate chemistry student to a distinguished professor and researcher highlights the transformative power of science in shaping the future of medicine.

 

Publication

  1. Radiation-induced brain injury in non-human primates: A dual tracer PET study with [11C]MPC-6827 and [11C]PiB

    • Authors: Naresh Damuka, George W. Schaaf, Mack Miller, Caleb Bradley, Bhuvanachandra Bhoopal, Ivan Krizan, Krishna K. Gollapelli, Christopher T. Whitlow, J. Mark Cline, Kiran K. Solingapuram Sai
    • Year: 2025

 

  1. The ÎČ-Secretase 1 Enzyme as a Novel Therapeutic Target for Prostate Cancer

    • Authors: Hilal A. Rather, Sameh Almousa, Ashish Kumar, Mitu Sharma, Isabel Pennington, Susy Kim, Yixin Su, Yangen He, Abdollah R. Ghara, Kiran Kumar Solingapuram Sai et al.
    • Year: 2023

 

  1. Development and Optimization of 11C-Labeled Radiotracers: A Review of the Modern Quality Control Design Process

    • Authors: Paul Josef Myburgh, Kiran Kumar Solingapuram Sai
    • Year: 2023

 

  1. Binding Parameters of [11C]MPC-6827, a Microtubule-Imaging PET Radiopharmaceutical in Rodents

    • Authors: Avinash H. Bansode, Bhuvanachandra Bhoopal, Krishna Kumar Gollapelli, Naresh Damuka, Ivan Krizan, Mack Miller, Suzanne Craft, Akiva Mintz, Kiran Kumar Solingapuram Sai
    • Year: 2023

 

  1. PET Imaging of [11C]MPC-6827, a Microtubule-Based Radiotracer in Non-Human Primate Brains

    • Authors: Naresh Damuka, Paul W. Czoty, Ashley T. Davis, Michael Nader, Susan H. Nader, Suzanne Craft, Shannon L. Macauley, Lindsey K. Galbo Thomma, Phillip M. Epperly, Christopher T. Whitlow et al.
    • Year: 2020

 

  1. One-pot synthesis of novel tert-butyl-4-substituted phenyl-1H-1,2,3-triazolo piperazine/piperidine carboxylates, potential GPR119 agonists

    • Authors: Nagaraju Bashetti, J.V. Shanmukha Kumar, Naresh Varma Seelam, B. Prasanna, Akiva Mintz, Naresh Damuka, Sriram Devanathan, Kiran Kumar Solingapuram Sai
    • Year: 2019

 

Conclusion

Dr. Kiran K. Solingapuram Sai has established himself as a leading expert in radiopharmaceutical sciences, contributing significantly to translational imaging research. His work in PET radiopharmaceutical production and quality assurance underscores his role in advancing medical imaging techniques. His academic and research contributions make him a valuable asset in the field of radiology and molecular imaging.

Ali Mehri | Neuroscience | Neuroscience Research Pioneer Award

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Dr. Ali Mehri | Neuroscience | Neuroscience Research Pioneer Award

Dr. Ali Mehri Babol, Noshirvani University of Technology, Iran.

Dr. Ali Mehri is a prominent physicist whose academic journey has bridged the fields of solid-state physics, data science, and complex systems. With a Ph.D. in Solid State Physics from the University of Zanjan, his research explores novel interdisciplinary areas such as text mining, complex networks, and thermal and electronic transport in nanostructures. His work, particularly in the application of physical principles to data mining and linguistic studies, has significantly contributed to both theoretical and applied physics. Additionally, his research on the statistical properties of irrational numbers and the connection between Zipf’s exponent and language distribution has broadened the scope of complex systems analysis.

Profile

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Early Academic Pursuits 🎓

Dr. Ali Mehri began his academic journey in physics with a focus on solid-state physics. He completed his Bachelor’s degree in Solid State Physics at Kharazmi University in Tehran, Iran, in 2002. His passion for condensed matter physics led him to pursue a Master’s degree at the Institute for Advanced Studies in Basic Sciences (IASBS), Zanjan, where he focused on colloidal monolayers in the presence of periodic light fields. Under the guidance of Professor Mir Faez Miri, he laid the foundation for his future research. In 2008, Dr. Mehri earned his Ph.D. in Solid State Physics from the University of Zanjan, where he studied the role of entropy in text mining under the supervision of Professor Amir Hossein Darooneh. This pivotal research provided him with a unique perspective that blends physics with data science.

Professional Endeavors đŸ’Œ

After completing his education, Dr. Mehri embarked on a career in academia, where he has established himself as a dedicated educator and researcher. He currently serves as a faculty member at the Department of Physics, Babol Noshirvani University of Technology. His professional journey is marked by his deep involvement in research, teaching, and mentoring students, particularly in the fields of data and text mining, complex networks theory, and nanostructures. Over the years, he has collaborated with various national and international researchers, enhancing the global visibility of his work in these specialized areas of study.

Contributions and Research Focus 🔬

Dr. Mehri’s research interests lie at the intersection of physics and data science. His work on text mining using the Hurst exponent is a significant contribution to the emerging field of applying physical principles to analyze textual data. He has also explored the intriguing topic of irrational numbers by studying statistical distances to determine the order of digits. Furthermore, Dr. Mehri’s research extends to the correlation between Zipf’s exponent and the geographical distribution of human languages, which connects his expertise in complex networks theory with linguistics. His exploration of thermal and electronic transport in nanostructures adds a solid foundation to his contributions in condensed matter physics.

Accolades and Recognition 🏅

Throughout his academic career, Dr. Ali Mehri has received numerous accolades for his research contributions. His work, particularly in data mining and complex networks, has earned him recognition both in Iran and internationally. Dr. Mehri’s research has been cited in various scientific journals, showcasing the relevance and impact of his work in advancing knowledge within his fields. His academic achievements have solidified his reputation as a forward-thinking physicist who bridges the gap between theoretical and applied sciences.

Impact and Influence 🌍

Dr. Mehri’s work has had a profound impact on various scientific communities, particularly in the fields of data mining, complex networks, and nanostructures. By introducing concepts like the Hurst exponent to text mining and exploring the relationships between statistical distances and irrational numbers, his research has influenced not only physics but also the interdisciplinary applications of data science. His contributions to understanding the connection between language distribution and Zipf’s law have opened new avenues for researchers in both physics and linguistics, highlighting the diverse impact of his work across disciplines.

Legacy and Future Contributions đŸ•°ïž

As Dr. Mehri continues to push the boundaries of research, his legacy will be defined by his ability to merge complex concepts from physics with innovative methodologies from data science. His future contributions are expected to further enhance the understanding of nanostructures, electronic transport, and complex systems. Moreover, his pioneering work in text mining and the analysis of irrational numbers has the potential to lead to groundbreaking advancements in computational physics and data analytics. As his research evolves, Dr. Mehri’s work will undoubtedly inspire future generations of physicists and data scientists, reinforcing his lasting influence in these fields.

Publication

  • Title: The complex networks approach for authorship attribution of books
    Authors: A Mehri, AH Darooneh, A Shariati
    Year: 2012

 

  • Title: Variation of Zipf’s exponent in one hundred live languages: A study of the Holy Bible translations
    Authors: A Mehri, M Jamaati
    Year: 2017

 

  • Title: A nonextensive modification of the Gutenberg–Richter law: q-stretched exponential form
    Authors: AH Darooneh, A Mehri
    Year: 2010

 

  • Title: Word ranking in a single document by Jensen–Shannon divergence
    Authors: A Mehri, M Jamaati, H Mehri
    Year: 2015

 

  • Title: The role of entropy in word ranking
    Authors: A Mehri, AH Darooneh
    Year: 2011

 

  • Title: Keyword extraction by nonextensivity measure
    Authors: A Mehri, AH Darooneh
    Year: 2011

 

  • Title: Tsallis entropy, escort probability and the incomplete information theory
    Authors: AH Darooneh, G Naeimi, A Mehri, P Sadeghi
    Year: 2010

 

  • Title: Text mining by Tsallis entropy
    Authors: M Jamaati, A Mehri
    Year: 2018

 

  • Title: Power-law regularities in human language
    Authors: A Mehri, SM Lashkari
    Year: 2016

 

  • Title: Non-extensive distribution of human eye photoreceptors
    Authors: A Mehri
    Year: 2017

 

Conclusion

Dr. Mehri’s professional career, marked by teaching and research at Babol Noshirvani University of Technology, has earned him national and international recognition. His research continues to influence fields as diverse as data science, linguistics, and condensed matter physics. Looking ahead, his work promises to advance the understanding of nanostructures and foster the further integration of physics with computational and data sciences. Dr. Mehri’s legacy will likely continue to inspire future generations of scientists, underscoring the importance of interdisciplinary collaboration in driving scientific progress.

Hiroshi Yamada | Neuroscience | Excellence in Innovation

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Mr. Hiroshi Yamada | Neuroscience | Excellence in Innovation

Mr. Hiroshi Yamada, Medical/Tsukuba, Japan.

H. Yamada, born in Kasugai, Aichi, Japan, has built an impressive academic and professional career in neuroscience. After earning his Bachelor of Science from Tohoku University, he pursued a Master’s degree at Osaka University and later obtained his Ph.D. from Kyoto Prefectural University of Medicine. His research journey took him from postdoctoral studies in Japan to New York University, where he collaborated with renowned neuroscientist Paul W. Glimcher. Returning to Japan, he served as Section Chief at the National Center of Neurology and Psychiatry before joining the University of Tsukuba, where he progressed from Assistant Professor to Associate Professor. His research focuses on neural mechanisms, contributing significantly to neuroscience through both theoretical and practical advancements.

Profile

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🎓 Early Academic Pursuits

H. Yamada’s academic journey reflects a deep-rooted passion for science and medicine. Born on September 9, 1977, in Kasugai, Aichi, Japan, he pursued a Bachelor of Science degree from the Faculty of Science at Tohoku University, graduating in 2000. Driven by a desire to deepen his understanding of human biology, he earned his Master of Arts from the Faculty of Medicine at Osaka University in 2002. His academic pursuits culminated in a Ph.D. from the Graduate School of Kyoto Prefectural University of Medicine in 2005, where he laid the groundwork for his future research in neuroscience.

🧠 Professional Endeavors in Neuroscience

H. Yamada’s professional career began with postdoctoral research at Kyoto Prefectural University of Medicine under the mentorship of Minoru Kimura, focusing on advanced neurological studies. His pursuit of global scientific exposure led him to New York University in 2008, where he worked with renowned neuroscientist Paul W. Glimcher. Upon returning to Japan, Yamada took on a leadership role as Section Chief at the National Center of Neurology and Psychiatry, National Institute of Neuroscience, from 2011. This role was pivotal in shaping his expertise in neurological research, ultimately leading to his tenure as Assistant Professor at the University of Tsukuba in 2013, and later as Associate Professor in 2022.

🔬 Contributions and Research Focus

Throughout his career, H. Yamada has been dedicated to unraveling the complexities of the human brain. His research primarily focuses on neuroscience, exploring neural mechanisms underlying behavior and cognition. At the University of Tsukuba, he has contributed significantly to the understanding of brain functions, merging experimental data with theoretical models to advance the field. His collaborations with international experts have enriched his approach, making his work both diverse and impactful.

🏅 Accolades and Recognition

Yamada’s contributions to neuroscience have earned him recognition within the academic community. His leadership roles and tenured position at the University of Tsukuba reflect his outstanding research and teaching capabilities. His work at prestigious institutions like New York University and the National Center of Neurology and Psychiatry has further solidified his reputation as a respected neuroscientist, contributing to both national and international scientific advancements.

🌍 Impact and Influence

H. Yamada’s research has had a profound impact on the field of neuroscience, influencing both academic circles and clinical practices. His studies on neural behavior have provided insights that bridge the gap between theoretical neuroscience and practical applications, aiding in the development of treatments for neurological disorders. As an educator, he has mentored numerous students, fostering the next generation of neuroscientists.

🚀 Legacy and Future Contributions

Looking ahead, H. Yamada is committed to expanding the horizons of neuroscience through innovative research and global collaborations. His legacy is not only reflected in his published work but also in the students and researchers he has inspired. As he continues his journey at the University of Tsukuba, his focus remains on advancing scientific knowledge and contributing to the global understanding of the human brain.

💡 A Lifelong Dedication to Science

H. Yamada’s life is a testament to the power of curiosity and dedication. From his early academic days in Tohoku to his current role as an Associate Professor, he has consistently pursued excellence in neuroscience. His journey underscores the importance of interdisciplinary research, mentorship, and the relentless quest for knowledge, leaving a lasting mark on the scientific community.

Publication

  • Title: Tonically active neurons in the primate caudate nucleus and putamen differentially encode instructed motivational outcomes of action
    Authors: H. Yamada, N. Matsumoto, M. Kimura
    Year: 2004

 

  • Title: Roles of the lateral habenula and anterior cingulate cortex in negative outcome monitoring and behavioral adjustment in nonhuman primates
    Authors: T. Kawai, H. Yamada, N. Sato, M. Takada, M. Matsumoto
    Year: 2015

 

  • Title: Thirst-dependent risk preferences in monkeys identify a primitive form of wealth
    Authors: H. Yamada, A. Tymula, K. Louie, P.W. Glimcher
    Year: 2013

 

  • Title: Juxtacellular labeling of tonically active neurons and phasically active neurons in the rat striatum
    Authors: H. Inokawa, H. Yamada, N. Matsumoto, M. Muranishi, M. Kimura
    Year: 2010

 

  • Title: Free choice shapes normalized value signals in medial orbitofrontal cortex
    Authors: H. Yamada, K. Louie, A. Tymula, P.W. Glimcher
    Year: 2018

 

  • Title: Tonically active neurons in the striatum encode motivational contexts of action
    Authors: M. Kimura, H. Yamada, N. Matsumoto
    Year: 2003

 

  • Title: Tonic firing mode of midbrain dopamine neurons continuously tracks reward values changing moment-by-moment
    Authors: Y. Wang, O. Toyoshima, J. Kunimatsu, H. Yamada, M. Matsumoto
    Year: 2021

 

  • Title: Roles of centromedian parafascicular nuclei of thalamus and cholinergic interneurons in the dorsal striatum in associative learning of environmental events
    Authors: K. Yamanaka, Y. Hori, T. Minamimoto, H. Yamada, N. Matsumoto, et al.
    Year: 2018

 

  • Title: Inactivation of the putamen selectively impairs reward history-based action selection
    Authors: M. Muranishi, H. Inokawa, H. Yamada, Y. Ueda, N. Matsumoto, M. Nakagawa, et al.
    Year: 2011

 

  • Title: Goal-directed, serial and synchronous activation of neurons in the primate striatum
    Authors: M. Kimura, N. Matsumoto, K. Okahashi, Y. Ueda, T. Satoh, T. Minamimoto, et al.
    Year: 2003

 

Conclusion

H. Yamada’s career is a reflection of his dedication to advancing the understanding of the human brain. His academic achievements, leadership roles, and research contributions have left a lasting impact on the neuroscience community. As he continues his work at the University of Tsukuba, his legacy is defined not only by his scientific discoveries but also by his mentorship and influence on future generations of researchers. His journey stands as an inspiring example of the pursuit of knowledge and the transformative power of science.

Karim Abbasian | Functional Brain Connectivity | Excellence in Research

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Assist Prof Dr.Karim Abbasian | Functional Brain Connectivity | Excellence in Research

Assist Prof Dr. Karim Abbasian University of Tabriz Iran

Dr. Karim Abbasian is an Associate Professor at the University of Tabriz, specializing in optical systems, quantum electronics, and nanophotonics. With a PhD in Optical Integrated Circuit Design, he has over 55 peer-reviewed publications and extensive teaching experience in advanced topics like Quantum Optics and Nanotechnology. His research focuses on all-optical systems, solar cells, and biosensors. Dr. Abbasian has held key administrative roles, including Rector of University of Bonab, and has been recognized for his contributions to research and teaching. His work is instrumental in advancing optical and quantum technologies for future applications.

profile

google scholar

Academic Position

Current Role: Associate Professor, Faculty of Electrical & Computer Engineering, University of Tabriz

Educational Background

Ph.D. in Optical Integrated Circuit Design from University of Tabriz, 2008Thesis: Electromagnetically Induced Transparency (EIT) for Realization of All-Optical Systems.M.Sc. in Electronic Engineering, University of Tarbiat Modarres, 1997.Thesis: On-Line Recognition of Handwritten Farsi Characters.B.Sc. in Electronic Engineering, University of Urumieh, 1994.

Teaching Experience

Courses taught at undergraduate, master’s, and PhD levels include:Magnetic Resonance Imaging (MRI), NanoPhotonics, Quantum Electronics, NanoElectronics, BioElectromagnetics, Quantum Optics, and more.

Research Interests

All-Optical Systems and Devices.Plasmonic and Nanophotonic Systems.Quantum Computing, Semiconductor Nanocrystals.Solar Cell Design, Optical Biosensors.Electromagnetic Fields in Tissue Engineering.Quantum Electronics, Quantum Cellular Automata.

Administrative Roles

Rector, University of Bonab (2017-2019).Dean, Faculty at University of Bonab (2002-2005).Vice Dean at University of Tabriz and University of Bonab (1999-2005).

Honors & Awards

Distinguished Researcher at University of Tabriz (2009, 2011, 2014).Distinguished Teacher at University of Tabriz (2010)Multiple employment grades for research and management excellence (2011, 2019)

📚 Publications

  • Ultra-fast all-optical plasmonic switching in near infra-red spectrum using a Kerr nonlinear ring resonator
    T. Nurmohammadi, K. Abbasian, R. Yadipour
    Optics Communications, 2018

 

  • All-optical analog-to-digital converter based on Kerr effect in photonic crystal
    D. Jafari, T. Nurmohammadi, M.J. Asadi, K. Abbasian
    Optics & Laser Technology, 2018

 

  • A proposal for a demultiplexer based on plasmonic metal–insulator–metal waveguide-coupled ring resonator operating in near-infrared spectrum
    T. Nurmohammadi, K. Abbasian, R. Yadipour
    Optik, 2017

 

  • Long wavelength infrared photodetector design based on electromagnetically induced transparency
    M. Zyaei, H.R. Saghai, K. Abbasian, A. Rostami
    Optics Communications, 2008

 

  • Low voltage, high modulation depth graphene THz modulator employing Fabry–Perot resonance in a metal/dielectric/graphene sandwich structure
    B. Jafari, H. Soofi, K. Abbasian
    Optics Communications, 2020

 

  • Modeling and analysis of room-temperature silicon quantum dot-based single-electron transistor logic gates
    M. Miralaie, M. Leilaeioun, K. Abbasian, M. Hasani
    Journal of Computational and Theoretical Nanoscience, 2014

 

  • Ultra-fast all-optical plasmon induced transparency in a metal–insulator–metal waveguide containing two Kerr nonlinear ring resonators
    T. Nurmohammadi, K. Abbasian, R. Yadipour
    Journal of Optics, 2018

 

  • Efficiency optimization in a rainbow quantum dot Solar cell
    A. Rostami, K. Abbasian, N. Gorji
    International Journal on Technical and Physical Problems of Engineering, 2011

 

  • A novel proposal for ultra-high resolution and compact optical displacement sensor based on electromagnetically induced transparency in ring resonator
    R. Yadipour, K. Abbasian, A. Rostami, Z. Koozekanani
    Progress In Electromagnetics Research, 2007

 

  • Analytical modeling of quality factor for shell type microsphere resonators
    R. Talebi, K. Abbasian, A. Rostami
    Progress In Electromagnetics Research B, 2011

 

  • All-optical tunable mirror design using electromagnetically induced transparency
    K. Abbasian, A. Rostami, Z. Koozekanani
    Progress In Electromagnetics Research M, 2008

 

  • A three-core hybrid plasmonic polarization splitter designing based on the hybrid plasmonic waveguide for utilizing in optical integrated circuits
    L. Shirafkan Dizaj, K. Abbasian, T. Nurmohammadi
    Plasmonics, 2020

Conclusion

Dr. Karim Abbasian’s extensive academic and research career highlights his significant contributions to the fields of optics, photonics, and nanotechnology. His leadership roles and innovative research on all-optical systems, solar cells, and biosensors underscore his commitment to advancing both theoretical knowledge and practical applications. His achievements, including numerous publications and teaching excellence, place him as a prominent figure in the scientific community. Dr. Abbasian’s work continues to shape the future of optical and quantum technologies, driving progress in critical areas that have wide-reaching implications for science and industry.