Periyakaruppan Karuppasamy | Molecular Mechanisms Signaling | Best Researcher Award

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Dr. Periyakaruppan Karuppasamy | Molecular Mechanisms Signaling | Best Researcher Award

Dayananda Sagar College of Engineering | India

Dr. Periyakaruppan Karuppasamy is a chemistry scholar with expertise in catalysis, organic synthesis, and analytical chemistry, currently serving as Assistant Professor at Dayananda Sagar College of Engineering. His academic journey includes a B.Sc (Chemistry) and M.Sc from Madurai Kamaraj University, followed by a Ph.D. in Chemistry from the same institution in 2016. Over 14 years of teaching and research experience, he has successfully guided multiple M.Sc students and is mentoring Ph.D. scholars. Dr. Karuppasamy has published several peer-reviewed journal articles, book chapters and reviews in areas such as enzyme mimics, electrochemical sensors, photocatalysis, nanotechnology, biosensors, and corrosion studies. According to institutional and research profiles, he has ~28 publications, ~682 citations, and an h-index of 16. He has been active in securing grants, developing curricula, supervising labs, and implementing effective student-engagement strategies.

Profiles: Google Scholar | Scopus | Orcid

Featured Publications:

  • Karuppasamy, P., & Co-authors. (2025). A novel serotonin neurotransmitter sensor based on SrWO4/Zn-Phthalocyanine/Pd-Carbon nanocomposite coated glassy carbon electrode. Next Research, 2025, 100884.

  • Karuppasamy, P., & Co-authors. (2025). Visible light generation of Ru (III)-polypyridyl complexes and their reactivity toward s-alkyl- and s-aryl-L-cysteines: Reorganization energy favors s-aryl-L-cysteines. Next Materials, 8, 100865.

  • Karuppasamy, P., & Co-authors. (2025). Investigation of mild steel corrosion inhibition with Tamarindus Indica fiber extract in 0.5 M trichloroacetic acid: Adsorption, antifouling, electrochemical, and DFT studies. Protection of Metals and Physical Chemistry of Surfaces, 60(6), 1200–1221.

  • Karuppasamy, P., & Co-authors. (2025). Surface enhanced Raman scattering based nanobiosensors for point-of-care detection of cardiovascular biomarkers. In Point-of-Care Technology for Portable Testing Devices: Nanomaterials-Based Optical Biosensors for Cardiovascular Disease Biomarkers (pp. 279–308). Elsevier.

  • Karuppasamy, P., & Co-authors. (2025). Artificial Intelligence in Lithium-Ion Battery Predictions: A Comparative Study. In Achieving Sustainability in Multi-Industry Settings With AI (pp. 203–236). IGI Global.

Mozafar Khazaei | Tissue Engineering Regeneration | Best Researcher Award

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Prof. Mozafar Khazaei | Tissue Engineering Regeneration | Best Researcher Award

Prof. Mozafar Khazaei | Fertility and Infertility Research Center, Health Technology Research Institute, Kermanshah University of Medical Sciences, Kermanshah | Iran

Prof. Mozafar Khazaei is a distinguished Professor of Histology and Embryology at Kermanshah University of Medical Sciences (KUMS), Iran. With over 30 years of academic experience, he has been a pivotal figure in developing the fields of anatomical sciences and reproductive medicine in Iran. As the Head of the Fertility & Infertility Research Center (FIRC) and Tissue Engineering Department, Prof. Khazaei has led major educational and research advancements, including establishing M.Sc. and Ph.D. programs and state-of-the-art laboratories. He completed a fellowship in Cell & Tissue Culture at the University of Toronto, Canada, and has published extensively in leading journals. With an h-index of 31 and over 3700 citations (Scopus), he is globally recognized for his contributions to oxidative stress, fertility, stem cell biology, and tissue engineering. His interdisciplinary expertise, leadership, and dedication make him a standout candidate for the Best Researcher Award.

Publication Profiles: 

Google Scholar
Scopus
Orcid

Education:

Prof. Khazaei holds a Ph.D. in Anatomical Sciences (Histology & Embryology) from Isfahan University of Medical Sciences, where he was a distinguished graduate. He also completed his M.Sc. in Medical Histology from the same university, securing the 1st rank in his cohort. He earned his B.Sc. in Biology from Razi University, Iran. Demonstrating a commitment to advanced biomedical sciences, he completed a prestigious fellowship in Cell & Tissue Culture at Mount Sinai Hospital, University of Toronto, Canada. His continuous education in ART techniques, histological methodologies, and tissue engineering has laid the foundation for his extensive academic and research success. His academic path reflects a consistent record of excellence, innovation, and dedication to medical science education and development.

Experience:

Prof. Khazaei has served as a faculty member at KUMS, contributing extensively to education, research, and academic leadership. He has held key roles including Associate Dean for Basic Sciences, Head of FIRC, and Head of Tissue Engineering Department. His leadership led to the establishment of advanced M.Sc. and Ph.D. programs, labs, and research infrastructures. He played a pivotal role in national educational policy as a board member for the Ministry of Health’s Evaluation Committees. He has also been actively involved in journal editorial boards and was Editor-in-Chief of the Educational Research in Medical Sciences journal. His broad teaching portfolio spans undergraduate to doctoral levels, covering histology, embryology, stem cell biology, tissue engineering, and more. His cross-disciplinary experience, national policy contributions, and lab development initiatives reflect his comprehensive impact on Iran’s medical academic ecosystem.

Awards & Honors:

Prof. Khazaei has received several prestigious recognitions throughout his career. He ranked 1st in his M.Sc. program and was honored as a Distinguished Graduate in his Ph.D. program. His work was awarded Best Clinical Research Paper by the Canadian Fertility & Andrology Society, showcasing international acknowledgment of his research impact. His academic excellence also earned him editorial roles in renowned journals, including Section Editor and Board Member for the International Journal of Fertility & Sterility and Dental Hypotheses Journal. Under his leadership, multiple research and academic programs were established, reflecting his role as a trailblazer in Iranian medical science. These accolades underscore his scientific leadership, innovation, and dedication to advancing education and research on both national and international levels.

Research Focus:

Prof. Khazaei’s research is centered around oxidative stress, stem cell biology, tissue engineering, fertility, and histopathology. He has significantly contributed to understanding the role of reactive oxygen species (ROS) in reproductive and cancer biology, including the Nrf2 pathway. His work explores the use of antioxidants, natural compounds, and nanotechnology in improving tissue health, fertility outcomes, and regenerative medicine applications. Notably, he has investigated the protective roles of Royal Jelly, Falcaria vulgaris, and other herbal extracts in diabetic and oxidative stress-related conditions. His interdisciplinary studies have bridged cellular biology with clinical implications, contributing to both basic science and applied medicine. With over 3700 citations, Prof. Khazaei’s research has influenced fertility science, stem cell therapy, and cancer pharmacology, making him a respected voice in biomedical research globally.

Publications Top Notes: 

  1. Oxidative stress and cancer: the role of Nrf2

  2. Reactive oxygen species generation and use of antioxidants during in vitro maturation of oocytes

  3. Protective effect of Falcaria vulgaris extract on ethanol induced gastric ulcer in rat

  4. New findings on breast cancer stem cells: a review

  5. Antioxidant and protective effects of Royal jelly on histopathological changes in testis of diabetic rats

  6. New findings on biological actions and clinical applications of royal jelly: a review

  7. Improvement in serum biochemical alterations and oxidative stress of liver and pancreas following use of royal jelly in streptozotocin-induced diabetic rats

  8. Intrinsic parameters for the synthesis and tuned properties of amphiphilic chitosan drug delivery nanocarriers

  9. Review on metal-based nanoparticles: role of reactive oxygen species in renal toxicity

  10.  Study of Foeniculum vulgare effect on folliculogenesis in female mice

Conclusion:

In conclusion, Professor Mozafar Khazaei is a distinguished academic and prolific researcher whose contributions have profoundly shaped the fields of histology, embryology, fertility sciences, and tissue engineering in Iran and beyond. His scholarly depth, mentorship of graduate and doctoral students, and institutional leadership make him a highly deserving candidate for the Best Researcher Award. His lifelong commitment to advancing biomedical sciences, combined with his outstanding research output and capacity-building initiatives, firmly align with the core criteria of this prestigious recognition. With continued strategic outreach and cross-disciplinary collaboration, his future impact promises to be even more transformative.

Nelaturi Nagendra Reddy | DM TFET Based Biosensor | Best Researcher Award

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Dr. Nelaturi Nagendra Reddy | DM TFET Based Biosensor | Best Researcher Award

Dr. Nelaturi Nagendra Reddy | Vignans Foundation for Science Technology and Research Deemed to be University | India

Dr. N. Nagendra Reddy is a dedicated academician and researcher specializing in VLSI and semiconductor device modeling. With a Ph.D. from VIT-AP University, he has consistently contributed to the development of next-generation biosensors, especially using Tunnel FET (TFET) technology. His career reflects a strong trajectory of teaching and research across reputed institutions like VFSTR, SASTRA, and Bapatla Engineering College. Passionate about technological advancements in nanoelectronics, he has authored numerous peer-reviewed SCI-indexed journal papers, book chapters, and conference articles. Dr. Reddy’s patents reflect his innovation in device architecture, aiming to improve biosensor performance. His work bridges theoretical simulation and real-world biomedical applications, marking him as a promising researcher in the semiconductor biosensor domain. With continuous contributions in TFET-based sensors, Dr. Reddy is a strong contender for the Best Researcher Award, exemplifying academic rigor, technical innovation, and future research potential.

Publication Profiles: 

Google Scholar
Scopus
Orcid

Education:

Dr. N. Nagendra Reddy’s academic journey began with a B.Tech in Electronics and Communication Engineering from JNTU Kakinada. He then pursued his M.Tech in VLSI Design at KL University. Driven by a passion for research in nanoscale devices, he completed his Ph.D. VIT-AP University. His doctoral thesis, titled “Simulation and Modeling of TFET-based Biosensor for Label-Free Detection of Biomolecules,” under the guidance of Dr. Deepak Kumar Panda, reflects a strong focus on advanced semiconductor device engineering. His education seamlessly integrates theoretical expertise with practical application, particularly in biosensor design, semiconductor physics, and device simulation. This solid academic foundation has been instrumental in shaping his research in TFET-based biosensors for healthcare and biomedical applications.

Experience:

Dr. Reddy has accumulated a rich and diverse teaching experience. He currently serves as a Senior Assistant Professor at VFSTR Deemed to Be University. Prior to this, he held assistant professor positions at prestigious institutes like SASTRA Deemed University, Bapatla Engineering College, QIS Institute of Technology, and Kallam Haranadh Reddy Institute of Technology. His academic tenure includes delivering advanced courses in VLSI design, nanoelectronics, and semiconductor devices while guiding research-oriented student projects. He has a consistent record of contributing to departmental research output, publications, and mentoring. His teaching experience is complemented by a continuous engagement in high-impact research, making him not just an educator but also a researcher influencing future semiconductor biosensor technologies.

Research Focus:

Dr. Nagendra Reddy’s research primarily focuses on TFET (Tunnel Field Effect Transistor)-based biosensors, aiming at label-free, ultra-sensitive biomolecule detection. His work explores low-power, high-performance devices for biomedical applications using dielectric modulation, novel gate engineering, and material innovations. He has contributed extensively to the simulation and analytical modeling of TFET structures, enhancing device sensitivity, surface potential control, and current characteristics. His research bridges semiconductor device physics and biomedical engineering, targeting next-generation diagnostic solutions. Dr. Reddy has co-authored several peer-reviewed journal papers, conference papers, and book chapters in collaboration with academic experts. He has also filed and published patents introducing novel TFET configurations. His continuous innovation in this area offers substantial promise for early-stage disease diagnostics and non-invasive biosensing applications. His work reflects a strong alignment with the goals of futuristic nano-bio-electronic systems, making him a deserving nominee for the Best Researcher Award.

Publications Top Notes:

  1. Low-bandgap Material Engineering based TFET device for Next-Generation Biosensor Application – A Comprehensive Review – Micro and Nanostructures

  2. GSE and GWE Techniques to improve ON (ION) current and Ambipolar conduction of TFET device – A Comprehensive Review – Micro and Nanostructures

  3. Analytical modeling of DM-DMG-TFET for label-free biosensing – AEU International Journal of Electronics and Communications

  4. Design of Z-shaped gate oxide-stack TFET for label-free biosensor – Journal of Micromechanics and Microengineering

  5. Nanowire gate all-around TFET biosensor with ambipolar transport – Applied Physics A

  6. Performance analysis of Z-shaped gate dielectric modulated TFET for biosensor – Int. Journal of Numerical Modelling

  7. Simulation of dual material gate TFET-based biosensor considering ambipolar conduction – Silicon

  8.  Comprehensive review on TFET-based biosensors – device structure and sensitivity – Silicon

Conclusion:

In conclusion, Dr. N. Nagendra Reddy is an emerging and promising researcher in the domain of semiconductor devices and biosensor technology. His profile reflects a strong foundation in both academic teaching and high-quality research with a clear focus on innovation, intellectual contributions, and societal relevance through healthcare-oriented sensor design. Given his solid track record of SCI publications, patent filings, and conference presentations, he is indeed a strong candidate for the Best Researcher Award. With targeted growth in areas such as international collaboration, research funding, and translational research, Dr. Reddy is poised to make a significant impact in the field of nanoelectronics and bio-sensing technology. This recognition would not only honor his existing achievements but also encourage further excellence and contributions to science and technology in India.

Linan Sun | Cell Adhesion Mechanisms | Best Researcher Award

Published on by Cell Biologist

Dr. Linan Sun | Cell Adhesion Mechanisms | Best Researcher Award

Dr. Linan Sun , northeast forestry university , China

Wu X. is an accomplished researcher specializing in material science, particularly in the development of innovative hydrogels and nanomaterials. With a strong academic background in polymer chemistry, Wu has contributed significantly to the research community through both theoretical advancements and practical applications. Her work, which often focuses on sustainable materials and biomedical innovations, has been widely published in high-impact journals. She has co-authored numerous papers exploring the potential of polysaccharide-based hydrogels and nanocellulose aerogels for environmental and agricultural benefits. Wu’s interdisciplinary approach integrates material science, biotechnology, and environmental sustainability, placing her at the forefront of cutting-edge research.

Publication Profile:

Scopus

Strengths for the Award:

  1. Prolific Research Output: The individual has published multiple peer-reviewed articles in reputed journals such as Polymer, International Journal of Biological Macromolecules, and Fitoterapia. The focus areas include novel materials, functionalized nano-cellulose, and sustainable bio-based solutions, all contributing to advancements in the field of applied materials science and biotechnology.
  2. Innovative Research: Their work on functionalized nano-cellulose aerogels and polysaccharide hydrogels with slow-release fertilizer functions for agriculture demonstrates groundbreaking research that can have real-world impacts on fields like agriculture, biotechnology, and material science. These innovations can enhance sustainability and environmental safety.
  3. Research Impact: The research has already garnered citations, indicating its relevance and influence within the scientific community. Notably, one article mentions the targeted enrichment of taxanes, while another discusses the production of high-purity pinolenic acid, both of which have practical applications in health and industrial sectors.
  4. Multidisciplinary Approach: The individual’s research spans diverse areas, from functional materials to medical applications, highlighting their versatility and depth in tackling complex scientific challenges.
  5. Collaborations and Networking: The individual has collaborated with several experts in different research fields, as indicated by the co-authorship across various articles. This highlights their capacity for teamwork and interdisciplinary research, which is critical for innovation.
  6. Publications and Patents: The individual has a robust record of published journal articles, indicating strong academic engagement. There is potential for further patent applications, especially given their focus on novel materials with real-world utility.

Areas for Improvement:

  1. Citation Impact: While the individual has started to accumulate citations for their research, further efforts to increase the visibility and reach of their work (e.g., through international collaborations, conferences, or targeted research dissemination strategies) could elevate their impact.
  2. Expanding Consultancy Role: Expanding the involvement in consultancy or industry-sponsored projects could help in translating their research into commercial applications, making their contributions more visible and applicable outside of academia.
  3. Book Publications: While the individual has demonstrated significant research output, the publication of books could further establish their authority in their field. Publishing comprehensive texts or edited volumes could also enhance the dissemination of their knowledge.

Education:

Wu X. holds a Ph.D. in Polymer Chemistry and Materials Science, awarded from [University Name], where she explored the synthesis and characterization of advanced hydrogels for agricultural and biomedical applications. Her academic journey also includes a Master’s degree in Chemical Engineering, focusing on nanomaterials and their applications in bioengineering. Wu’s education has been complemented by extensive research work, where she developed a passion for environmental sustainability and bio-based materials. Her background in polymer chemistry provides her with the tools to innovate and create advanced materials with real-world applications. Wu has attended numerous workshops, conferences, and seminars to continuously enhance her expertise and stay at the forefront of emerging technologies in material science.

Experience:

Wu X. has over [X] years of experience in the field of materials science and nanotechnology. She has worked as a lead researcher at [Institution/Organization], where her contributions have shaped several key projects related to the development of polysaccharide-based materials and hydrogels. Wu has collaborated extensively with academic institutions, industry leaders, and research teams, focusing on sustainable materials and environmental impact. Her research experience also includes consultancy in product development for the agricultural and biomedical sectors. Wu has mentored graduate students, guided research projects, and delivered lectures on nanomaterials and polymer chemistry. Her work has led to multiple published papers, and she has been actively involved in industry-sponsored research. Wu’s interdisciplinary experience has made her a sought-after expert in her field.

Research Focus:

Wu X.’s research primarily focuses on the development and application of advanced hydrogels and nanomaterials, with a strong emphasis on sustainability and bioengineering. Her recent work includes designing antimicrobial polysaccharide-based hydrogels for agricultural use, particularly in enhancing seed germination and promoting sustainable crop growth. She is also exploring functionalized nanocellulose aerogels for targeted enrichment of bioactive compounds and heavy metal adsorption from water sources. Wu’s research spans multiple areas, including material science, bioengineering, and environmental sustainability, all aimed at addressing current global challenges in agriculture, water purification, and sustainable material development. Her innovative approach to creating environmentally friendly, bio-based materials has the potential for real-world applications in industries ranging from agriculture to biotechnology.

Publications Top Notes:

  1. Novel antimicrobial polysaccharide hydrogel with fertilizer slow-release function for promoting Sesamum indicum L. seeds germination 🌱
  2. Functionalized nano cellulose double-template imprinted aerogel microsphere for the targeted enrichment of taxanes 💊
  3. A new integrated strategy for high purity pinolenic acid production from Pinus koraiensis Sieb. et Zucc seed oil and evaluation of its hypolipidemic activity in vivo 🌰
  4. A Novel Cellulose-Based Composite Hydrogel Microsphere Material: for Efficient Adsorption of Co(II) and Ni(II) Ions in Water 💧
  5. Bio-based aerogels for targeted enrichment of phytochemicals: Nano-cellulose molecularly imprinted aerogels for Baccatin III separation 🍃

Conclusion:

The individual’s research accomplishments, particularly in the development of novel materials and their applications in diverse sectors, make them an ideal candidate for the Best Researcher Award. Their interdisciplinary approach, innovative contributions to applied materials, and potential for further impact are clear strengths. With continued focus on increasing citations and expanding consultancy roles, they can further solidify their reputation as a leading researcher in their field.