Gökçe Karaotmarlı Güven | Cancer Cell Biology | Best Research Article Award

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Mrs. Gökçe Karaotmarlı Güven | Cancer Cell Biology | Best Research Article Award

Mrs. Gökçe Karaotmarlı Güven | Biruni University, Faculty of Pharmacy | Turkey

Gökçe Karaotmarlı Güven, born on July 22, 1996, is a dynamic and passionate Research Assistant with a strong academic foundation in pharmaceutical sciences. She earned her Bachelor’s degree from Biruni University, Faculty of Pharmacy in 2020, and is currently pursuing her Ph.D. in Pharmaceutical Technology at Health Sciences University, where she is deeply involved in cutting-edge nanomedicine research. Her expertise lies in carbon quantum dots, drug delivery systems, and bio-nanotechnology. Gökçe has collaborated on innovative research projects and has contributed significantly to the scientific community through high-impact publications and patent filings. Her interdisciplinary research combines pharmaceutical technology, nanoscience, and biotechnology, aiming to advance targeted drug delivery for diseases like cancer. She is recognized for her analytical mindset, scientific curiosity, and collaborative spirit, which fuel her aspiration to become a leading figure in pharmaceutical nanotechnology. Gökçe continues to explore novel therapeutic technologies to address some of the most pressing challenges in modern medicine.

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✅ Strengths for the Award:

  1. Innovative Research:
    Gökçe has demonstrated a clear focus on high-impact, novel research—especially with her work on boron-doped carbon quantum dots for targeted drug delivery and cancer therapy. Her work represents a pioneering intersection of nanotechnology and pharmaceutical sciences.

  2. High-Quality Publications:
    She has published in internationally respected journals such as Pharmaceuticals, Applied Sciences, and Journal of Research in Pharmacy. The topics she covers—quantum drug development, phytochemical-based wound therapies, and ocular drug delivery—are timely and significant to global health.

  3. Patent Contributions:
    With three patent applications (2024–2025), her research is not only academic but also translational and innovation-driven, showing real-world applicability—a vital criterion for research excellence awards.

  4. Collaborative and Interdisciplinary Work:
    Gökçe has worked with both national and international teams, indicating strong teamwork, adaptability, and leadership in multidisciplinary settings.

🔄 Areas for Improvement:

  1. Broader Publication Indexing:
    Although her work is high quality, more publications in top-tier Q1 journals indexed by PubMed/Scopus/Web of Science would further validate her research’s global impact and improve her visibility.

  2. Post-Doctoral Research Exposure:
    Expanding her research experience internationally through postdoctoral fellowships or collaborations abroad could enhance the depth of her academic profile and increase her competitiveness for global-level research awards.

  3. Greater Conference Participation:
    Active presentation in international conferences, symposiums, or research summits would broaden her academic reach and help disseminate her innovations to a larger audience.

🎓 Education:

Gökçe Karaotmarlı Güven’s educational background reflects her commitment to pharmaceutical sciences and innovation. She obtained her Bachelor’s degree from the Faculty of Pharmacy at Biruni University in 2020, where she developed a solid understanding of pharmaceutical chemistry and drug formulation. Currently, she is pursuing a Ph.D. in Pharmaceutical Technology at the Health Sciences University, Hamidiye Faculty of Pharmacy. Her doctoral research is focused on the synthesis, biodistribution, and pharmacokinetics of boron-doped carbon quantum dots—highly advanced nanomaterials with potential applications in drug delivery and cancer therapy. Under the mentorship of Prof. Dr. Neslihan Üstündağ Okur and co-advisor Prof. Dr. İsmail Tuncer Değim, she is conducting high-level research that blends nanotechnology with targeted therapeutic systems. Her academic training is complemented by active involvement in laboratory-based innovation and scholarly writing, making her well-prepared for an impactful career in both academia and the pharmaceutical industry.

💼 Experience:

Gökçe Karaotmarlı Güven is currently working as a Research Assistant at Health Sciences University, where she contributes to numerous multidisciplinary projects in the field of pharmaceutical nanotechnology. Her professional journey began with laboratory internships and academic projects during her undergraduate years, focusing on drug formulation and ocular drug delivery systems. During her Ph.D., she has played a pivotal role in designing and characterizing nanocarriers for targeted drug delivery, particularly in cancer treatment and wound healing. Her hands-on experience includes formulation science, analytical instrumentation, preclinical biodistribution studies, and in vitro pharmacokinetics. Gökçe has been involved in patentable inventions and has co-authored multiple high-impact journal articles in international journals. Her collaborations span across Turkish and international institutions, showcasing her ability to work in team-based research environments. Her strengths lie in research design, scientific communication, and a deep understanding of advanced drug delivery systems, making her an asset to any pharmaceutical research team.

🔬 Research Focus:

Gökçe Karaotmarlı Güven’s research centers on the intersection of nanotechnology and pharmaceutical sciences, particularly in the development of carbon quantum dots (CQDs) for targeted drug delivery. Her doctoral thesis involves the preparation, biodistribution, and pharmacokinetic evaluation of boron-doped carbon quantum dots and composite carbon quantum dots, aimed at enhancing drug delivery efficiency in cancer treatment. Her interests extend to quantum drug technologies, ocular drug delivery systems, and hydrogel formulations containing bioactive molecules. Through her collaborative research, she explores the role of nanoformulations in wound healing, antimicrobial applications, and personalized medicine. Gökçe is particularly passionate about applying nanotechnology to solve real-world therapeutic challenges, especially in cancer and ophthalmic care. Her work is informed by a multidisciplinary approach, blending pharmaceutical chemistry, nanoscience, and biotechnology. Her research is innovative, patentable, and addresses unmet needs in the current pharmaceutical landscape, positioning her as a rising scholar in next-generation drug delivery systems.

📚 Publications Top Notes:

  1. 🧬 Quantum Drugs (Q-Drugs): A New Discovery and Taboo Breaking Approach; Producing Carbon Quantum Dots from Drug MoleculesPharmaceuticals, 2025-05-22

  2. 🌿 Nanoformulations Loaded with Phytochemicals for Combating Wound Infections and Promoting Wound HealingApplied Sciences, 2025-05-12

  3. 👁️ In situ gels loaded with naringin as ocular drug delivery carriers; development and preliminary characterizationJournal of Research in Pharmacy, 2024

  4. 💧 Preparation and characterization of carbopol based hydrogels containing dexpanthenolAnkara Universitesi Eczacilik Fakultesi Dergisi, 2023-06-12

📝 Conclusion:

Gökçe Karaotmarlı Güven stands out as a highly promising young researcher whose work is innovative, scientifically sound, and application-focused. Her contributions to the development of novel drug delivery systems, particularly through carbon quantum dots and nanomedicine strategies, mark her as a deserving candidate for the Best Research Article Award.

Her work aligns with the values such awards seek to recognize: originality, relevance, translational impact, and collaborative strength. With continued growth in international exposure and expanded publication reach, she will not only be a worthy recipient now but also an influential leader in pharmaceutical nanotechnology in the future.

Eunhee Lee | Neuronal Cell Biology | Best Research Article Award

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Dr. Eunhee Lee | Neuronal Cell Biology | Best Research Article Award

Dr. Eunhee Lee, Daegu Gyeongbuk Medical Innovation Foundation, K-MEDI hub, South Korea

Dr. Eun-Hee Lee, Ph.D., is a distinguished biomedical researcher with expertise in therapeutic ultrasound and neurobiology. Currently serving as Senior Researcher and Head of the Advanced Technology Department at the Medical Device Development Center, DGMIF, South Korea, she has consistently contributed to the advancement of focused ultrasound applications in neurological disorders. With over a decade of research experience spanning government institutions and clinical collaborations, Dr. Lee has published extensively in peer-reviewed journals on brain delivery mechanisms, neuroinflammation, and neurodegeneration. Her pioneering studies have deepened our understanding of the blood-brain barrier and the therapeutic potential of ultrasound. Her work stands at the forefront of translational neuroscience, aiming to enhance drug delivery and brain repair mechanisms. Dr. Lee’s dedication to impactful and clinically relevant research makes her a strong contender for the Best Research Article Award.

Publication Profile: 

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✅ Strengths for the Award

  1. Innovative Research Focus:
    Dr. Lee’s work on focused ultrasound (FUS)-mediated blood-brain barrier (BBB) disruption is at the cutting edge of neurotherapeutics and non-invasive brain drug delivery. Her investigations hold promise for treating neurodegenerative disorders like Alzheimer’s disease and traumatic brain injuries.

  2. Extensive Peer-Reviewed Publications:
    With over 15 high-quality, peer-reviewed articles published from 2019 to 2024 in reputable journals like Scientific Reports, Frontiers in Neuroscience, and Biomedicines, her research output reflects consistent and impactful contributions.

  3. Interdisciplinary Approach:
    Her integration of biomedical engineering, imaging, and neurobiology enhances the translational value of her findings. Numerical modeling and simulation studies further strengthen the clinical feasibility of her techniques.

  4. Clinical and Preclinical Impact:
    Dr. Lee’s work bridges preclinical models (rats, skull simulations) with potential human applications, offering real translational pathways for drug delivery across the BBB.

  5. Leadership and Collaboration:
    As the Head of the Advanced Technology Department at DGMIF, she demonstrates leadership in medical innovation and fosters collaboration between academia, hospitals, and research institutes.

⚠️ Areas for Improvement

  1. Greater International Collaboration:
    While her work is deeply embedded in Korean institutions, expanding partnerships internationally could amplify her research reach and global influence.

  2. Clinical Trial Transition:
    Much of her published work is preclinical. Advancing to clinical trials or human pilot studies would significantly increase the translational impact of her findings.

  3. Public Engagement and Visibility:
    Enhanced visibility through global neuroscience or biomedical engineering conferences could further validate and showcase her research excellence.

🎓 Education:

Dr. Eun-Hee Lee received all her academic training from Chonnam National University, Kwangju, South Korea. She earned her Ph.D. (2007–2010) and M.S. (2005–2007) in Biological Sciences and Technology, gaining extensive knowledge in cellular and molecular biology. Her B.S. in Genetic Engineering (2001–2005) laid the groundwork for her interest in biomedical innovations and neurogenetics. During her graduate and doctoral studies, she focused on cellular pathways and gene expression relevant to neurodegenerative diseases and molecular interventions. Her academic journey shaped her multidisciplinary perspective, merging genetics, bioengineering, and neurobiology. These foundations have enabled her to pursue cutting-edge research on the blood-brain barrier, drug delivery systems, and brain stimulation. Dr. Lee’s strong academic background provides her with the theoretical and technical expertise essential for high-impact research.

🧪 Experience:

Dr. Eun-Hee Lee has more than 14 years of progressive research experience. Since 2017, she has led the Advanced Technology Department at DGMIF, where she develops novel medical devices using therapeutic ultrasound. Prior to this, she worked as a Research Scientist at the Korea Atomic Energy Institute’s Advanced Radiation Technology Institute (2015–2017), where she explored radiation-mediated biological responses. Between 2013 and 2015, she contributed to TB and molecular microbiology research at the Korean Institute of Tuberculosis. Her postdoctoral fellowship (2011–2012) at the NIH’s Division of HIV/AIDS and Tumor Viruses expanded her expertise into virology and immunopathology. Dr. Lee’s multidisciplinary roles across leading institutions demonstrate her adaptability, leadership, and commitment to translational science. Her professional trajectory shows strong contributions to national research priorities in healthcare and medical technology.

🔬 Research Focus:

Dr. Eun-Hee Lee’s research centers on focused ultrasound (FUS) as a non-invasive modality for drug delivery and neural repair. Her work explores ultrasound-mediated blood-brain barrier (BBB) disruption to enhance targeted therapeutic access to the brain. She also investigates ultrasound stimulation’s effects on neurogenesis, neuroinflammation, and neuroprotection in various neurological models including Alzheimer’s disease and spinal cord injury. Another significant area of focus includes numerical modeling of skull structures to improve the precision of transcranial FUS applications. Through collaborations with clinicians and physicists, Dr. Lee has produced evidence-based methodologies for safer, more effective BBB modulation. Her integrative approach, combining bioengineering, neuroimmunology, and computational simulation, is impactful in the field of therapeutic neuromodulation and has implications for treating neurodegenerative and cerebrovascular disorders.

📚 Publications Top Notes: 

  • 🧠 Numerical Investigation of Layered Homogeneous Skull Model for Simulations of Transcranial Focused Ultrasound (2024)

  • 🔥 The New Insight into the Inflammatory Response Following Focused Ultrasound-Mediated Blood-Brain Barrier Disruption (2022)

  • 🧪 Methylene Blue Delivery via Focused Ultrasound Reduces Neural Damage and Amyloid-Beta by AQP-4 Upregulation (2022)

  • 🐀 Novel Animal Model of Spontaneous Cerebral Petechial Hemorrhage Using Focused Ultrasound in Rats (2022)

  • ♻️ Ultrasound Stimulation Improves Inflammation Resolution and Functional Recovery After Spinal Cord Injury (2022)

  • 🚑 Relationship Between Treatment Types and BBB Disruption in Acute Ischemic Stroke: Two Case Reports (2022)

  • 🧲 Effects of Transducer Displacement on Focused Ultrasound in the Rat Brain (2022)

  • 📉 BBB Disruption After Syncope: A DCE-MRI Case Report (2021)

  • 🧪 Verification of BBB Disruption Using Rat Model with Human Skull (2021)

  • 💧 Localized Water Molecule Transport Modulation Post-FUS BBB Disruption (2021)

  • 🚨 DCE-MRI for Evaluating BBB Disruption in Traumatic Brain Injury: Review (2021)

  • 🧬 TREM2 Promotes Natural Killer Cell Development in pNK Cells (2021)

  • 🌿 Gintonin Enhances Donepezil Brain Delivery via LPA and VEGF Receptors (2021)

  • 🔄 Cyclophilin A is a Ligand for TREM2 in Myeloid Cells (2021)

  • 🧠 Local Differences in BBB Permeability Induced by Focused Ultrasound (2020)

  • 💉 Advanced FUS Protocol Improves Doxorubicin Delivery in Rat Brain (2019)

  • 🔄 FUS-Induced Diminished P-glycoprotein via JNK Pathway in Cerebral Vessels (2019)

🧾 Conclusion:

Dr. Eun-Hee Lee is a highly suitable candidate for the Best Research Article Award. Her work is scientifically rigorous, clinically relevant, and methodologically innovative. The focus on ultrasound-mediated drug delivery through the BBB is a transformative area in neuroscience and drug delivery technology. Her comprehensive research output, leadership, and translational potential strongly position her among top contenders for recognition. Encouraging clinical application and broader dissemination will only enhance the already substantial value of her contributions.

Naoki Harada | Molecular Mechanisms Signaling | Best Researcher Award

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Dr. Naoki Harada | Molecular Mechanisms Signaling | Best Researcher Award

Dr. Naoki Harada, Osaka Metropolitan University, Japan

Naoki Harada is an Associate Professor at Osaka Metropolitan University, Japan, with extensive expertise in molecular biology, biochemistry, endocrinology, and nutrition. He earned his Ph.D. in Life Sciences from Osaka Prefecture University in 2007. Over the past two decades, Harada has made significant contributions to understanding the physiological and biochemical mechanisms underpinning metabolic diseases, particularly type 2 diabetes. His research, characterized by high citation impact (H-index of 25), centers on pancreatic β-cell function and metabolic regulation. He has published 77 peer-reviewed articles and holds a patent related to therapeutic interventions. Harada has collaborated with leading scientists like Professors Hiroshi Inui and Ryoichi Yamaji, strengthening his academic footprint in both national and international circles. A member of multiple scientific societies, Harada continues to influence the field through impactful research, industry collaboration, and educational leadership.

Publication Profile: 

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✅ Strengths for the Award:

  1. Consistent Research Output

    • 77 peer-reviewed publications in reputable journals (SCI, Scopus).

    • Recent high-impact studies published in Journal of Biological Chemistry, Scientific Reports, and FASEB BioAdvances.

    • Active research profile with an H-index of 25 and over 1,785 citations.

  2. Innovative Scientific Contributions

    • Identified REDD2 as a novel therapeutic target for type 2 diabetes—bridging basic research with translational medicine.

    • Works across disciplines such as molecular biology, endocrinology, and nutritional biochemistry.

  3. Project Leadership & Industry Engagement

    • Led or participated in 14 major research projects.

    • 5 consultancy/industry-based projects, reflecting application-oriented research.

  4. Academic and Collaborative Network

    • Strong academic collaborations with Professors Hiroshi Inui and Ryoichi Yamaji.

    • Member of prestigious scientific societies (e.g., Japanese Biochemical Society, Japan Society of Nutrition and Food Science).

  5. Scientific Versatility

    • Contributions span fundamental mechanisms (e.g., oxidative stress, insulin signaling) to dietary interventions (e.g., mogrol, oleamide).

    • Demonstrates ability to bridge molecular insights with systemic physiological outcomes.

⚙️ Areas for Improvement:

  1. International Visibility and Engagement

    • Expanding participation in international conferences and editorial boards could elevate his global scientific standing.

    • Pursuing cross-border collaborations would further enrich the translational value of his work.

  2. Commercialization and Patent Activity

    • While one patent is noted, increased focus on intellectual property development and biomedical commercialization could further validate his applied research strength.

  3. Outreach and Communication

    • More active public science communication (e.g., webinars, policy advocacy, media coverage) would amplify the societal impact of his research.

🎓 Education:

Naoki Harada received his Ph.D. in Life Sciences from Osaka Prefecture University, Osaka, Japan, in September 2007. His doctoral studies laid the foundation for his interdisciplinary research in molecular biology, biochemistry, and endocrinology. Harada’s academic path was driven by a keen interest in the cellular and molecular mechanisms underlying metabolic regulation, particularly in relation to glucose homeostasis and pancreatic function. His education provided him with a solid grounding in experimental techniques, critical thinking, and scientific communication, which have become hallmarks of his later work. The institution, known for excellence in biosciences, enabled Harada to cultivate a strong research acumen. His academic training was complemented by exposure to applied research, linking basic science with clinical and nutritional applications—an approach that he has continued to emphasize throughout his career. His strong educational background plays a pivotal role in his current research endeavors and professional development.

💼 Experience:

Dr. Naoki Harada began his academic career in 2008 as an Assistant Professor at the Graduate School of Life and Environmental Sciences, Osaka Prefecture University. He was promoted to Lecturer in 2015, and subsequently to Associate Professor in 2019. Since 2022, he has served as Associate Professor at the Graduate School of Agriculture, Osaka Metropolitan University. Harada has consistently combined teaching with intensive research, mentoring graduate students while advancing his lab’s focus on metabolic diseases and endocrine physiology. His experience includes leading 14 research projects, consulting on 5 industry-linked nutrition initiatives, and co-authoring over 75 scientific papers. His experience reflects a blend of academic leadership, scientific innovation, and multidisciplinary collaboration. Notably, Harada’s role in identifying REDD2 as a therapeutic target exemplifies his contribution to translational science. He maintains strong academic partnerships and actively contributes to several professional societies, making him a respected figure in Japan’s scientific community.

🔬 Research Focus:

Naoki Harada’s research is at the intersection of molecular biology, endocrinology, and nutrition science, with a particular focus on pancreatic β-cell physiology and glucose metabolism. He investigates how oxidative stress, hormonal signals, and metabolic regulators influence insulin secretion and β-cell viability. One of his pivotal contributions is identifying the REDD2 gene as a negative regulator of β-cell function, offering novel therapeutic targets for type 2 diabetes mellitus. His studies also explore nutrient-sensing pathways, G-protein-coupled receptors, and hormonal modulation of energy metabolism. Harada’s recent work delves into the effects of dietary compounds like mogrol and oleamide on metabolic health, linking molecular mechanisms to real-world dietary interventions. His ability to bridge bench science with clinical and nutritional applications sets his research apart. Through collaborations with leading experts and high-impact publications, Harada continues to advance knowledge in the prevention and treatment of metabolic disorders.

📚 Publications Top Notes:

  • 🧬 REDD2 confers pancreatic β-cell dysfunction in high-fat diet-fed miceJournal of Biological Chemistry, 2025

  • 🦷 Androgens suppress ST3GAL1/4, modulating mucin glycosylation and microbiota in miceBioscience, Biotechnology, and Biochemistry, 2025

  • 🍟 CRTC1 in MC4R cells regulates dietary fat intakeFASEB BioAdvances, 2024

  • 💉 Insulin reduces ER stress-induced apoptosis in INS-1 β-cellsPhysiological Reports, 2024

  • 🍬 Mogrol activates GPBAR1 and insulin secretion, alleviates hyperglycemiaScientific Reports, 2024

  • 🔥 Androgen receptor suppresses β-adrenoceptor-mediated thermogenesisJournal of Biological Chemistry, 2022

  • 🏥 Age-dependent sex differences in NAFLD in TSOD and db/db micePLOS ONE, 2022

  • 🐭 Dietary oleamide attenuates obesity in caged miceBioscience, Biotechnology, and Biochemistry, 2022

  • 🌿 Curcumin targets GPR55 receptornpj Science of Food, 2022

  • 💪 Oleamide rescues muscle atrophy in small-caged miceBritish Journal of Nutrition, 2021

🧾 Conclusion:

Dr. Naoki Harada demonstrates a clear trajectory of research excellence, grounded in scientific rigor and driven by impactful biomedical questions. His ability to identify molecular mechanisms (e.g., REDD2’s role in β-cell dysfunction) and propose therapeutic directions sets him apart as a leading academic in metabolic disease research. His publication record, industry collaborations, and professional memberships underscore a mature and influential academic career.

Carlos Cruchaga | Neuronal Cell Biology | Best Researcher Award

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Dr. Carlos Cruchaga | Neuronal Cell Biology | Best Researcher Award

Dr. Carlos Cruchaga, Washington Univeristy, United States

Dr. Carlos Cruchaga is a tenured Professor at Washington University School of Medicine, with joint appointments in Psychiatry, Genetics, and Neurology. He is the Director of the NeuroGenomics and Informatics Center and leads multiple high-impact cores including the Knight ADRC, DIAN Genetics Core, and Biorepository Core for initiatives like the Dystonia Coalition and Aging Adult Brain Connectome. Internationally recognized for his pioneering work in neurodegenerative diseases, Dr. Cruchaga specializes in integrating multi-omic datasets to identify novel genetic and molecular mechanisms underlying Alzheimer’s disease and other neurological disorders. He has authored over 340 peer-reviewed publications and continues to lead major NIH-funded projects. With a strong commitment to translational research, he also contributes to tool development for omics data analysis. His work consistently bridges the gap between basic research and clinical application, making him a deserving candidate for the Best Researcher Award.

Publication Profile: 

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✅ Strengths for the Award:

  • Leadership: Director of NeuroGenomics and Informatics Center; leads major genetics cores (Knight ADRC, DIAN, Dystonia Coalition, AABC).

  • Research Impact: Over 346 peer-reviewed publications with significant contributions in Alzheimer’s Disease (AD), neurodegeneration, multi-omics, and genetic epidemiology.

  • Translational Focus: Discoveries such as rare variants in AD-related genes (APP, PSEN1, PSEN2, PLD3, TREM2) and biomarker identification have major clinical implications.

  • Global Collaborations: Works with international research consortia including ADNI, GERAD, and Alzheimer’s Research UK, showing both scientific influence and collaboration.

  • Recognition: Invited speaker at high-level conferences; selected for the prestigious Spanish “Excellence Campus 2005”.

  • Innovation: Pioneered multi-omic and bioinformatic pipelines for biomarker discovery.

⚠️ Areas for Improvement:

  • Public Outreach: While academically exceptional, public or patient-facing outreach or science communication isn’t highlighted.

  • Diversity Initiatives: Potential to expand into mentorship programs or initiatives focused on increasing diversity in genomics.

  • Commercialization: There is room to emphasize translational science through startups, patents, or technology transfer.

🎓 Education:

Dr. Cruchaga earned his undergraduate degree in Biochemistry from the University of Navarra, Pamplona, Spain (1996–2000). He continued his graduate studies at the same institution, obtaining an MA (2000–2002) followed by a PhD in Biochemistry and Molecular Biology in 2005. His doctoral research, awarded Summa Cum Laude, focused on molecular mechanisms and biomarkers associated with neurodegenerative diseases. Dr. Cruchaga was selected among Spain’s top 18 PhD students to present his research at the “Excellence Campus 2005,” hosted by the Spanish Government and attended by Nobel Laureates. His training included foundational roles as a student and teaching assistant in the Department of Biochemistry and Molecular Biology, setting the stage for a career deeply rooted in research excellence and academic mentorship. This strong academic background has been instrumental in shaping his translational approach to complex neurological conditions like Alzheimer’s and dystonia.

💼 Experience:

Dr. Cruchaga has amassed extensive experience across academic, administrative, and research leadership roles. Since 2019, he has served as a Professor in Psychiatry, Genetics, and Neurology at Washington University. He is also the current Director of the NeuroGenomics and Informatics Center (since 2018), where he supervises multi-disciplinary teams and oversees high-throughput genomics operations. He leads cores in major initiatives such as the Knight Alzheimer’s Disease Research Center (ADRC), DIAN (Dominantly Inherited Alzheimer Network), and the Dystonia Coalition. Earlier roles include serving on the Alzheimer’s Association International Conference Scientific Program Committee (2014–2017), where he curated session topics, evaluated hundreds of abstracts, and chaired sessions. His international collaborations span omics, imaging, and computational biology, making him a leader in neurogenomics. These diverse roles have allowed Dr. Cruchaga to influence both scientific innovation and strategic planning within global neuroscience research initiatives.

🏅 Honors and Awards:

Dr. Cruchaga’s excellence has been recognized through numerous awards and invitations. In 2005, he was chosen for “Excellence Campus 2005,” a prestigious event featuring the top Spanish PhD students alongside Nobel Prize winners. He has received multiple invitations for keynote lectures and seminars at institutions across Europe and the U.S., including the University of the Basque Country, the Center for Applied Medical Research in Pamplona, and Washington University. He was a finalist for the O’Leary Award for Research in Neuroscience in 2009. His service as a Scientific Program Committee Member for the Alzheimer’s Association International Conference further underscores his leadership in the field. These accolades not only celebrate his scientific contributions but also affirm his status as a thought leader in neurodegenerative disease research. His peer-reviewed work has appeared in top-tier journals like Nature, Neuron, and Acta Neuropathologica.

🔬 Research Focus:

Dr. Cruchaga’s research centers on understanding the molecular and genetic underpinnings of neurodegenerative diseases, particularly Alzheimer’s disease, using integrative multi-omics approaches. His lab specializes in analyzing genomic, transcriptomic, proteomic, and metabolomic data from human biospecimens to uncover biomarkers, risk variants, and causal pathways. He has led groundbreaking studies identifying rare coding variants in genes like TREM2, PLD3, and APP, linking them to Alzheimer’s pathology. He applies advanced computational tools and machine learning to interpret high-dimensional data and translate findings into diagnostic and therapeutic strategies. As director of several national consortia cores (e.g., Knight ADRC, DIAN), he facilitates data-sharing and harmonization across global cohorts. His work also explores the genetic architecture of disorders like dystonia and peripheral neuropathy. The long-term goal of his research is to bridge omics data with clinical outcomes to enable personalized medicine in neurology.

📚 Publications Top Notes:

  1. 🧠 Rare variants in APP, PSEN1 and PSEN2 increase AD risk in late-onset familiesPLoS One (2012)

  2. 🧬 GWAS of CSF tau levels reveals novel AD risk variantsNeuron (2013)

  3. 🧠 Rare coding variants in PLD3 gene confer AD riskNature (2014)

  4. 🧠 TREM2 coding variants increase AD riskHuman Molecular Genetics (2014)

  5. 🧪 TREM2 variants linked to AD risk in African AmericansMol Neurodegeneration (2015)

  6. 🧫 Higher CSF soluble TREM2 linked to AD mutation statusActa Neuropathologica (2016)

  7. 🧪 Genetics of plasma analytes identifies novel biomarkersScientific Reports (2016)

  8. 🧬 Variants in Mendelian AD genes within ADSPJAD (2025)

  9. 🧠 RFC1 AAGGG repeat expansions common in neuropathyPreprint (2025)

  10. 🧪 Plasma proteomics uncovers novel AD biomarkersPreprint (2025)

🧾 Conclusion:

Dr. Carlos Cruchaga exemplifies the highest standards of neuroscience and genomics research. His contributions have advanced the global understanding of Alzheimer’s disease, making him a top-tier candidate for the Best Researcher Award. His scientific leadership, prolific output, and translational success position him as a standout in the biomedical field.

Andrew Moran | Molecular Mechanisms Signaling | Best Researcher Award

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Dr. Andrew Moran | Molecular Mechanisms Signaling | Best Researcher Award

Dr. Andrew Moran, University of Liverpool, United Kingdom

Dr. Andrew William Moran is a Research Associate at the University of Liverpool, UK, specializing in gastrointestinal physiology and nutrient sensing. With over two decades of research experience, his work has contributed significantly to understanding sugar sensing mechanisms and their implications for animal and human health. He holds dual honours in Biochemistry and Biological & Medicinal Chemistry from Keele University and a PhD in Biochemistry and Molecular Biology from the University of Liverpool. Dr. Moran has played key roles in industry-funded projects, notably with ADM International and Pancosma SA, contributing to patented innovations in sweetener technology. His cutting-edge research on intestinal transporters, gut hormones, and enteric nervous system function has led to over 20 peer-reviewed publications. His interdisciplinary collaborations span veterinary, nutritional, and molecular biology fields, making him a valuable asset in translational gastrointestinal science. His REF-submitted research underscores the real-world impact of his scientific contributions.

Publication Profile:  

Orcid

✅ Strengths for the Award:

  1. Robust Academic Foundation:

    • Dual honours in Biochemistry and Biological & Medicinal Chemistry (Keele University)

    • PhD in Biochemistry and Molecular Biology (University of Liverpool)

  2. Research Excellence & Impact:

    • Specializes in intestinal glucose transport, nutrient sensing, and gut-brain axis—key areas in both basic and applied science.

    • Authored 24 publications in Web of Science and 20 on PubMed, with an H-index of 15, indicating consistent impact.

  3. Translational & Applied Innovation:

    • Co-inventor on two international patents (WO2014033218A1 & WO2024121704A1) tied to sweetener additives—bridging lab discoveries with industrial application.

    • Projects funded by ADM International and Pancosma SA, highlighting industry trust.

  4. Collaborative Leadership:

    • Current research partnership with Dr. Ellen Roelfsema (Utrecht University) on metabolic syndrome in ponies—an example of cross-disciplinary collaboration.

    • Contribution to REF2021 and REF2024, showing national-level research evaluation engagement.

  5. Model Innovation:

    • Use of intestinal enteroids (mini-guts) in research, reflecting cutting-edge methodologies in gut physiology.

🧭 Areas for Improvement:

  • Editorial Leadership: There is no mention of editorial board roles or peer-review positions. Gaining visibility in editorial circles could amplify academic leadership.

  • Public Science Communication: While the research is strong, broader science communication (e.g., public outreach, open-access workshops, webinars) would further elevate his profile.

  • International Presence: While collaborations exist, a more visible presence through invited talks at global conferences or consortia could enhance reputation internationally.

🎓 Education:

Dr. Moran began his academic career with a BSc (Dual Honours) in Biochemistry and Biological & Medicinal Chemistry at Keele University from 1999 to 2002. He then pursued a PhD in Biochemistry and Molecular Biology at the University of Liverpool, completed in 2006. His doctoral work focused on molecular mechanisms governing intestinal function, laying the foundation for his future studies in gut nutrient sensing and transporter regulation. He has continually expanded his knowledge through postdoctoral training and research in gastrointestinal physiology. This includes both in vivo and in vitro experimental methodologies, ensuring a comprehensive approach to investigating intestinal health. His educational background supports a wide range of expertise—from fundamental biochemistry to applied animal nutrition and enteric neuroscience. His solid academic training is a core strength underpinning his contribution to translational and industry-focused research.

🧪 Experience:

Dr. Moran’s research experience spans over 20 years, with expertise in molecular physiology of the gastrointestinal system. Post-PhD, his early work investigated the regulation of intestinal SGLT1 transporters, combining cell-based and whole-organism experiments. From 2019 to 2022, he led a project exploring the adaptive responses of the gut to diet and development. His more recent work (2022–2024) focuses on sweetener additive development in swine, incorporating pig-specific intestinal enteroids. He is currently funded by ADM International and has previously collaborated with Pancosma SA, contributing to two international patents. Dr. Moran is also engaged in veterinary research, partnering with Utrecht University to study equine metabolic syndrome. He has served as both an academic researcher and a consultant on gut sensing and nutrient absorption. This blend of industry and academic experience strengthens his application for recognition as a leading researcher in the field of digestive sciences.

🔬 Research Focus:

Dr. Moran’s primary research interests lie in intestinal sugar and amino acid sensing, glucose transporter regulation, and the gut-brain axis. He uses both traditional and novel model systems, including intestinal enteroids (mini-guts), to explore physiological responses to dietary changes. His research particularly targets SGLT1 and GLUT2 transporters, sweet taste receptors (T1R2-T1R3), and enteroendocrine pathways, aiming to enhance feed efficiency and gut health in livestock. His focus on sweetener bioactivity has direct applications in agriculture and veterinary medicine. Additionally, Dr. Moran investigates how gut nutrient sensing influences systemic responses, including metabolic disorders like equine metabolic syndrome. By integrating biochemistry, molecular biology, and animal physiology, his research contributes to the development of functional feeds and dietary interventions. His work is highly translational, bridging laboratory research with field application, and has resulted in two patents, several international collaborations, and over 20 peer-reviewed journal articles, with research submitted for REF2021 and REF2024.

📚 Publications Top Notes:

  1. 📄 Luminal Sweet Sensing and Enteric Nervous System Participate in Regulation of Intestinal Glucose Transporter, GLUT2

  2. 📄 Nutrient sensing of gut luminal environment (Symposium: Proceedings of the Nutrition Society)

  3. 📄 Non-nutritive sweetener activation of the pig sweet taste receptor T1R2-T1R3 in vitro mirrors gut expression

  4. 📄 Toll-like receptor 9 in intestinal enteroendocrine cells induces cholecystokinin secretion

  5. 📄 High-Intensity Sweetener Enhances Intestinal SGLT1 and Improves Enteric Disorders in Rabbits

  6. 📄 Effect of Milk Replacer Composition on Intestinal Microbiota of Pre-ruminant Dairy Calves

  7. 📄 Host selectively shapes intestinal microbiota of carnivorous and omnivorous fish

  8. 📄 GLP-2 and Enteric Nervous System Regulate Intestinal Na+/Glucose Co-transport

  9. 📄 Deregulation of transcription factors in morbidly obese affects enteroendocrine cells

  10. 📄 Composition and diversity of pig gastrointestinal mucosa-associated microbiota under dietary influence

📝 Conclusion:

Dr. Andrew William Moran presents a strong and diverse research portfolio with a notable balance between fundamental science and industrial relevance. His innovation in nutrient sensing and gut physiology, coupled with active collaborations and patentable outputs, makes him an ideal candidate for the Best Researcher Award. With minor expansion in academic leadership and public engagement, Dr. Moran is poised to become a prominent figure in translational biosciences globally.

Mahedi Hasan | Plasma Medicine | Young Researcher Award

Published on by Cell Biologist

Mr. Mahedi Hasan | Plasma Medicine | Young Researcher Award

Mr. Mahedi Hasan, Shizuoka University, Japan

Mahedi Hasan is a promising Bangladeshi researcher with a strong academic and research foundation in genetic engineering and nanostructured optoelectronics. Currently pursuing his PhD at Shizuoka University, Japan, his work bridges plasma science with biomedical applications, focusing on cold atmospheric microplasma for drug delivery and cellular modulation. Previously, Mahedi completed his BS and MS in Genetic Engineering and Biotechnology from the University of Rajshahi with excellent academic distinction. He has published extensively in international peer-reviewed journals, collaborating with multinational research teams in Japan and Bangladesh. His passion lies in innovative, interdisciplinary approaches to solving complex biomedical problems, with a vision to improve targeted therapeutics. Mahedi has demonstrated remarkable dedication, from assisting in molecular biology labs to leading pioneering plasma-based biomedical research. With an emerging global presence and deep scientific curiosity, Mahedi Hasan is an ideal candidate for the Young Researcher Award.

Publication Profile: 

Orcid

✅ Strengths for the Award:

  1. Robust Academic Foundation

    • Strong academic performance in both undergraduate (CGPA 3.63) and postgraduate (CGPA 3.87) studies in Genetic Engineering & Biotechnology.

    • Currently pursuing a PhD in Optoelectronics and Nanostructure Science at a reputable Japanese institution (Shizuoka University), indicating a cross-disciplinary research approach.

  2. High-Impact Research Contributions

    • Authored 10+ peer-reviewed publications, several in Q1 journals, addressing cutting-edge topics such as cold atmospheric plasma (CAP), drug delivery, and cellular senescence.

    • Demonstrated innovation in plasma-assisted biomedical applications, including nose-to-brain delivery systems and BBB penetration strategies.

  3. International Collaboration and Experience

    • Collaborates with an international team across Bangladesh and Japan, engaging in complex projects with global relevance.

    • Ongoing research in Japan exposes him to high-end lab infrastructure and interdisciplinary training.

  4. Recognitions and Scholarships

    • Winner of the National Science and Technology (NST) Fellowship – 2019, a significant national-level endorsement of research potential.

    • Recipient of the Graduate Board Scholarship – 2019 for academic excellence.

  5. Consistent Research Focus

    • Maintains a clear research trajectory from plant plasma applications to nanotechnology and plasma-driven biomedical interventions, showcasing a deepening specialization.

🧩 Areas for Improvement:

  1. Independent Project Leadership

    • Most publications are collaborative; demonstrating leadership in principal investigator (PI)-style roles or initiating independent proposals would further establish his research autonomy.

  2. Wider Conference Participation

    • Engaging more frequently in international conferences and symposiums (oral/poster presentations) would enhance visibility and networking.

  3. Diversification of Funding Sources

    • Beyond national scholarships, pursuing international research fellowships (e.g., JSPS, DAAD, Marie Skłodowska-Curie) would show strategic initiative and grant-writing skills.

  4. Industrial/Clinical Relevance Expansion

    • Potential to link his plasma-based research with real-world medical or commercial applications through translational or industry-collaborative projects.

📘 Education:

Mahedi Hasan’s academic journey showcases consistent excellence. He is currently pursuing a Ph.D. in Optoelectronics and Nanostructure Science at Shizuoka University, Japan (2023–ongoing), where his research focuses on cold plasma-mediated drug delivery systems. He holds both Bachelor’s (2018) and Master’s (2019) degrees in Genetic Engineering and Biotechnology from the University of Rajshahi, Bangladesh. Despite delays in examination schedules, he graduated with distinction, securing a CGPA of 3.87/4.00 in MS and 3.63/4.00 in BSc. His academic records demonstrate a strong foundation in life sciences, biotechnology, and interdisciplinary research. Through his studies, he developed expertise in molecular biology, protein science, and advanced biomedical technologies. His transition into nanostructured optoelectronics further highlights his adaptability and commitment to advancing next-generation therapeutic technologies. Mahedi’s education reflects not only academic brilliance but also his progressive shift toward impactful, translational science.

🧪 Experience:

Mahedi Hasan has garnered substantial research experience across molecular biology and plasma-based therapeutics. He served as a Research Assistant at the

Apply now for the Plasma Medicine Research for Young Researcher Award—honoring early-career scientists advancing plasma technology in medicine. Open to researchers under 35. Submit your abstract and supporting documents today!

& Protein Science Lab in the Department of Genetic Engineering & Biotechnology, University of Rajshahi, from May 2019 to September 2023. His role included evaluating the effects of low-pressure dielectric barrier discharge (LPDBD) plasma on the growth, physiology, and nutritional properties of crops like wheat and maize. Prior to that, he completed a Research Internship in the same lab, where he explored the impact of LFGD plasma on agronomic and nutritional traits. His current Ph.D. research continues this trajectory, now exploring cold atmospheric microplasma for improved drug absorption across the blood-brain barrier and in cancer cells. Mahedi’s experience demonstrates a unique blend of plant and human model systems, bench-to-bedside translation, and strong interdisciplinary collaboration in both Bangladeshi and Japanese labs.

🏅 Awards and Honors:

Mahedi Hasan’s research potential has been recognized with several prestigious awards. In 2019, he received the National Science and Technology (NST) Fellowship from the Ministry of Science and Technology, Government of Bangladesh, a competitive award supporting emerging scientific talent. That same year, he was honored with the Graduate Board Scholarship by the University of Rajshahi, granted for his academic excellence during his Master’s studies. These accolades highlight his academic brilliance and commitment to impactful research. His continuous involvement in high-impact international collaborations and publications in reputable journals further solidify his reputation as a dedicated young scientist. As a Ph.D. candidate in Japan, he continues to contribute to frontier biomedical applications of microplasma technology. These honors, coupled with his impressive research output and global collaborations, make him an outstanding contender for any young researcher recognition.

🔬 Research Focus:

Mahedi Hasan’s research uniquely bridges biotechnology, plasma physics, and nanomedicine. His core focus is on the application of cold atmospheric microplasma in enhancing drug delivery, especially across complex barriers like the blood-brain barrier and into cancerous cells. His work explores microplasma-assisted nose-to-brain delivery systems, cellular senescence modulation, and targeted uptake of hydrophilic compounds. His research employs both cellular (in vitro) and animal (in vivo) models to study absorption efficiency, molecular interaction, and bioavailability of therapeutic agents. In his early work, he investigated plasma’s role in altering the physiology and nutritional value of crops. Now, through cutting-edge interdisciplinary collaborations at Shizuoka University, he is working at the frontier of plasma-assisted biomedical innovation, opening new doors for non-invasive drug delivery systems. This fusion of bioscience with physical sciences represents a novel, transformative approach, making his research both timely and globally significant.

📚 Publications Top Notes:

  1. 📄 Microplasma-Mediated Enhancement of FD-150 Uptake in HL-60 Cells

  2. 🧠 Absorption of FD-150 in Brain Endothelial Cells by Cold Atmospheric Microplasma

  3. 🧬 Exploring the Role of Microplasma for Controlling Cellular Senescence in Saccharomyces cerevisiae

  4. Voltage Dependent Effect of Spiral Wound Plasma Discharge on DBC1.2 Cellular Integrity

  5. 🧪 Enhancing Galantamine Distribution in Rat Brain Using Microplasma-Assisted Nose-to-Brain Drug Delivery

  6. 🧫 Absorption of FD-150 into White Blood Cells by Microplasma

  7. 🚧 In Vitro Drug Delivery through the Blood–Brain Barrier Using Cold Atmospheric Plasma

  8. 🧼 Lipidomics of Microplasma-Irradiated Cells at Optimized Discharge Conditions for Absorption of High-Molecule Drug

  9. 🐍 Toxins Profiles and Histological Impact of Trimeresurus erythrurus Venom: In Vitro and In Vivo Study

  10. 🧯 Evaluation of Bungarus caeruleus Venom and Antivenom Efficacy Used in Bangladesh

📝 Conclusion:

Mahedi Hasan emerges as a highly promising young researcher with a multidisciplinary profile rooted in biotechnology, plasma science, and nanostructure-based drug delivery systems. His solid academic background, commendable publication record, and international research involvement make him a strong contender for the Young Researcher Award. While he could benefit from taking on greater research leadership and wider dissemination of his work, his achievements to date clearly indicate excellent potential for impactful scientific contributions in the coming years.

Marija Gjorgoska | Cancer Cell Biology | Best Researcher Award

Published on by Cell Biologist

Mrs. Marija Gjorgoska | Cancer Cell Biology | Best Researcher Award

Mrs. Marija Gjorgoska | Institute of Biochemistry and Molecular Genetics, Faculty of Medicine, University of Ljubljana | Slovenia

Marija Gjorgoska is a dedicated biomedical researcher and teaching assistant at the Faculty of Medicine, University of Ljubljana, Slovenia. With a strong background in biochemistry, molecular biology, and bioinformatics, she has contributed significantly to cancer research, focusing on steroid hormone signaling in gynecological cancers. Her scientific work combines analytical expertise in LC-MS/MS with a solid foundation in molecular biology and statistical analysis using R programming. Marija is passionate about advancing clinical diagnostics and cancer treatment through high-precision biomolecular profiling. Her academic journey reflects international exposure through internships in the UK and Macedonia. She is known for her collaborative spirit and commitment to scientific rigor, which has led to multiple high-impact publications. Marija continues to mentor students and contribute to the academic community through her teaching role, making her a rising figure in molecular oncology research.

publication profile:

scopus

Strengths:

  1. High Research Productivity 📈
    Marija Gjorgoska has authored or co-authored 10 peer-reviewed publications in high-impact journals such as Progress in Lipid Research (IF 14.0), Trends in Endocrinology and Metabolism (IF 11.4), and Cancers. Her work shows consistent scientific output, often with first or shared first authorship.

  2. Cutting-Edge Technical Expertise 🔬
    She demonstrates advanced proficiency in LC-MS/MS method development, multi-steroid profiling, and bioinformatics (R programming). This makes her an expert in translational hormone research and biomarker discovery.

  3. Clinical Relevance and Innovation ⚕️
    Her research addresses urgent clinical challenges like endometrial cancer diagnosis and ovarian cancer drug resistance, applying modern analytical techniques combined with machine learning, which positions her at the forefront of personalized medicine.

  4. Recognition and Collaboration 🤝
    She has been awarded prestigious grants (e.g., Society of Endocrinology, UK), collaborated internationally (UK, Macedonia), and contributes to academia as a teaching assistant—all signs of an emerging research leader.

  5. Interdisciplinary Impact 🌐
    Marija effectively integrates molecular biology, biochemistry, analytical chemistry, and computational biology—indicative of her versatility and broad scientific impact.

Areas for Improvement:

  1. Independent Research Leadership
    While she has made substantial contributions as a junior and co-investigator, future work could benefit from establishing herself as a principal investigator or project leader, including securing her own research funding.

  2. Diversification of Research Themes
    Her focus has been predominantly on hormone-related cancers. Expanding into other disease models or mechanisms could broaden her impact and create new collaborative opportunities.

  3. Public Engagement and Outreach
    Enhancing her visibility through conference presentations, science communication, or community health initiatives would further solidify her standing as a leader and advocate for biomedical research.

Education :

Marija Gjorgoska is currently enrolled in a doctoral program in Biomedicine, specializing in Biochemistry and Molecular Biology at the University of Ljubljana. Her academic foundation includes a Master’s degree in Molecular Biology (2018–2021) from the same university, completed with an outstanding GPA of 9.52/10. She also gained international experience through a short-term internship at the University of Birmingham, UK, in 2023, focusing on advanced LC-MS/MS techniques for clinical sample analysis. Earlier in her academic career, she completed a long-term internship at the Research Center for Genetic Engineering and Biotechnology in Skopje, Macedonia (2017), where she worked on genetic diagnostics involving haemoglobinopathies, HPV, HBV, and HCV detection. Her education has consistently emphasized both theoretical knowledge and hands-on laboratory skills, particularly in analytical chemistry, molecular biology, and bioinformatics, all of which shape her current research endeavors in cancer diagnostics and hormonal regulation.

Experience:

Marija Gjorgoska has been actively engaged in research since 2020 as a Research Assistant at the Institute of Biochemistry and Molecular Genetics, Faculty of Medicine, University of Ljubljana. Her core responsibilities include developing and validating LC-MS/MS analytical methods, conducting proteomic and genetic analyses of cancer tissues, and performing bioinformatic evaluations using R programming. In October 2024, she also began serving as a Teaching Assistant for the course “Principles of Biochemistry,” demonstrating her commitment to education and mentorship. Marija’s prior internships have equipped her with valuable skills in prenatal and infectious disease diagnostics. Her research contributions span experimental planning, scientific writing, and instrument maintenance, establishing her as a versatile scientist. Her collaborative projects with international researchers and clinicians further underline her strength in translational biomedical research. This combination of teaching, laboratory, and analytical expertise supports her growing influence in molecular oncology.

Awards and Honors:

Marija Gjorgoska has been recognized for both academic and research excellence. In 2023, she was awarded the Practical Skills Grant by the Society of Endocrinology, UK, enabling her to undergo advanced training in LC-MS/MS at the University of Birmingham. Earlier, in 2021, she received the Krka Recognition with Special Praise for her Master’s thesis, highlighting her early promise as a researcher in molecular biology. Her scientific publications have appeared in top-tier journals such as Progress in Lipid Research and Trends in Endocrinology and Metabolism, some with impact factors exceeding 14.0. Notably, she earned shared first co-authorship in Methods in Enzymology for her work on enzymatic assay development. These accolades reflect her technical excellence, originality, and scientific contributions in the field of steroid metabolism and gynecological cancers. Marija’s achievements distinguish her as a young researcher with significant impact and high potential for further contributions to science and medicine.

Research Focus :

Marija Gjorgoska’s research focuses on the role of steroid hormones in the development and progression of gynecological cancers, particularly endometrial and ovarian cancers. Her work integrates analytical chemistry (LC-MS/MS), bioinformatics, and molecular biology to uncover diagnostic and prognostic biomarkers. She has developed multi-steroid profiling techniques to differentiate between normal and cancerous tissues, aiding early diagnosis. Marija’s studies also address the pre-receptor regulation of androgenic and estrogenic hormones, exploring their signaling dynamics at the tissue level. Using tools such as Mendelian randomization, she investigates genetic influences on hormone-related disease risk. Her interdisciplinary approach combines advanced mass spectrometry, statistical modeling, and clinical collaboration to translate bench science into meaningful medical applications. Through high-impact publications, she contributes to understanding hormone metabolism in cancer microenvironments, with the goal of informing targeted therapies and overcoming drug resistance. Her work is critical for advancing personalized medicine in hormone-driven malignancies.

Publications Top Notes:

  1. 📘 From fallopian tube epithelium to high-grade serous ovarian cancer: A single-cell resolution review of sex steroid hormone signalingProgress in Lipid Research, 2024

  2. 📘 Integration of androgen hormones in endometrial cancer biologyTrends in Endocrinology and Metabolism, 2022

  3. 📘 Steroid sulfatase and sulfotransferases in gynecological cancers: current status and perspectivesEssays in Biochemistry, 2024

  4. 📘 Estrogens and the Schrödinger’s cat in the ovarian tumor microenvironmentCancers, 2021

  5. 📘 Multi-Steroid Profiling and Machine Learning Reveal Androgens as Biomarkers for Endometrial CancerCancers, 2025

  6. 📘 Simultaneous measurement of 17 endogenous steroid hormones by LC-MS/MSJ. of Steroid Biochemistry and Molecular Biology, 2024

  7. 📘 11-oxyandrogens in normal vs. cancerous endometriumFrontiers in Endocrinology, 2024

  8. 📘 Targeting estrogen metabolism to overcome platinum resistance in ovarian cancerBiomedicine & Pharmacotherapy, 2024

  9. 📘 Effect of androgens on risk of endometriosis sub-phenotypes and ovarian neoplasmsJ. of Steroid Biochemistry and Molecular Biology, 2024

  10. 📘 Enzymatic assays for 17β-HSD types 1 and 2 using mass spectrometryMethods in Enzymology, 2023

Conclusion:

Marija Gjorgoska is a highly promising early-career researcher with a strong and growing international publication record, deep technical expertise in analytical biochemistry, and a clear focus on clinically relevant research. Her integration of hormonal pathway analysis with state-of-the-art analytical methods has already contributed valuable insights to the field of gynecological oncology. She has the academic rigor, curiosity, and collaborative drive essential for impactful science.

In my opinion, she is a highly suitable candidate for the Best Researcher Award. Continued mentorship and support toward independent research leadership will elevate her even further in the years to come.

Madeha Awad | Intracellular Transport Systems | Best Researcher Award

Published on by Cell Biologist

Assoc. Prof. Dr. Madeha Awad | Intracellular Transport Systems | Best Researcher Award

Assoc. Prof. Dr. Madeha Awad, Sohag university, Egypt

Dr. Madeha Ahmed Aboelfadl Awad is an accomplished Associate Professor in the Physics Department, Faculty of Science, Sohag University, Egypt. Born on January 27, 1979, she has established herself as a leading researcher in the field of nanomaterials physics, with a focus on the synthesis and characterization of metal, metal oxide, and oxysulfide nanostructures. Fluent in Arabic, English, and French, Dr. Awad has contributed extensively to sustainable material applications, including photocatalysis, photodetectors, and smart coatings. Her passion for scientific inquiry and dedication to environmental and energy-related innovations have positioned her as a significant academic voice in Egypt and internationally. Married and residing in Sohag, she continues to inspire through both her teaching and prolific research publications, contributing to over 10 international journal articles and conference presentations. Dr. Awad’s interdisciplinary approach bridges materials science with real-world industrial and environmental applications.

Publication Profile:

Scopus

✅ Strengths for the Award:

  1. Innovative Research Focus:
    Dr. Awad has demonstrated consistent innovation in synthesizing and characterizing advanced nanostructured systems (metal oxides, oxysulfides, and thin films), with real-world applications in environmental remediation, energy conversion, and optoelectronics.

  2. Publication Record:
    She has published 10+ articles in reputable international journals such as Physica Scripta and Journal of Materials Science: Materials in Electronics. Many of these works address pressing global challenges, including pollution control, clean energy, and smart coatings.

  3. Multidisciplinary Impact:
    Her work intersects physics, materials science, and environmental engineering, creating sustainable technologies like photocatalysts, hydrogen generation systems, and photodetectors.

  4. Active Conference Participation:
    Dr. Awad has presented at national and international scientific conferences, sharing her findings on SnO₂ thin films and transparent conductors, reflecting leadership in academic dissemination.

  5. Academic Development:
    She has completed multiple training courses in competitive research, digital transformation, and teaching methodologies, ensuring continuous growth and contribution to higher education quality.

🧩 Areas for Improvement:

  1. International Collaborations:
    While Dr. Awad is actively publishing, there is potential for expanding collaborations with global research institutes and industrial sectors to enhance the scope and visibility of her work.

  2. Research Funding Diversification:
    Engaging in international grant applications or large-scale collaborative projects would further strengthen her research sustainability and resource access.

  3. Visibility in High-Impact Conferences:
    Increasing participation in high-impact global conferences or symposiums (e.g., MRS, APS) could amplify her academic footprint and foster more research exchange.

🎓 Education:

Dr. Awad earned her B.Sc. in Physics with a very good degree from Sohag University in 2003. She pursued her M.Sc. in Solid State Physics (2008), focusing on the structural, electrical, and optical properties of Sn-Sb-Se compounds. In 2015, she received her Ph.D. in Nanomaterials Physics for her pioneering work on ZnO-based nanomaterials. Her Ph.D. research emphasized growth and characterization techniques vital for optoelectronic applications. In October 2020, she became an Associate Professor, having specialized in the synthesis and analysis of nanostructured systems, including metal oxides and oxysulfides, with targeted industrial uses. Her academic path reflects a deep commitment to solid-state physics, materials engineering, and nanotechnology. She has also enhanced her academic competencies with digital transformation, student assessment, and competitive research training, aligning her education with modern interdisciplinary needs and research innovations.

🧪 Professional Experience:

Dr. Awad began her academic journey as an Assistant Lecturer in 2013 at Sohag University’s Physics Department. Following the completion of her Ph.D. in 2015, she was promoted to Lecturer, contributing to undergraduate and postgraduate instruction while intensifying her research. In 2020, she was appointed Associate Professor in Materials Science. Over the years, Dr. Awad has participated in international conferences, served as a research mentor, and collaborated with national and international scholars. Her expertise in synthesizing thin films and evaluating their optical, structural, and electrical characteristics has enabled her to lead multiple applied research projects. In addition to teaching and supervision, she has completed various training programs on student assessment, digital transformation, and competitive research funding. Her holistic academic profile blends high-impact research with educational excellence, making her a valuable contributor to Egypt’s scientific and academic landscape.

🔬 Research Focus:

Dr. Madeha Awad’s research focuses on the synthesis, characterization, and application of nanostructured materials, particularly metal and metal oxide thin films. Her work addresses real-world challenges through environmentally friendly solutions such as photocatalysis for pollutant degradation, hydrogen generation from seawater, and smart coatings for self-cleaning surfaces. She is also active in developing photodetectors for environmental sensing. Her interdisciplinary approach integrates solid-state physics, material science, and environmental engineering. Her recent projects involve advanced nanocomposites like In2O3/CuO and TiO2-based systems, with optimized optoelectronic and wettability properties for diverse industrial applications. By modifying surface and structural properties of nano-films, Dr. Awad aims to enhance energy efficiency, sustainability, and environmental remediation technologies. She is a strong advocate for applied research and often collaborates on global research initiatives that promote clean energy and green technologies. Her vision merges innovation with impact.

📚 Publications Top Notes:

  1. 🔬 Photocatalytic characteristics of indium oxide, copper oxide and indium oxide/copper oxide thin films on plastic waste substrates for organic pollutants degradation

  2. 🔍 Influence of oxygen flow rates on the optoelectronic properties SnO2 thin films

  3. 🌿 A comparison between the effect of zinc oxide and zinc oxide nanoparticles on the growth and metabolic processes of Cosmarium sp

  4. 🌞 Highly sensitive TiO2 based photodetector for environmental sensing applications

  5. 🔦 Optoelectronic characteristics of In2O3/CuO thin films for enhanced visible-light photodetector

  6. 🧼 Photocatalysis, wettability and optical properties of N-doped Cu2O/CuO thin films for smart coating applications

  7. 💧 Surface wettability and photocatalytic activities of ZrOxNy/Au/TeO2 trilayers for antifogging coatings

  8. Some characteristics of Cu/Cu2O/CuO nanostructure heterojunctions and their applications in hydrogen generation from seawater

  9. 🌐 WNxOy prepared by oxidation of tungsten nitride as alternative photocatalyst to N-doped WO3

📝 Conclusion:

Dr. Madeha Ahmed Aboelfadl Awad exemplifies the qualities of a modern researcher who blends academic rigor with real-world impact. Her research in nanomaterials for environmental and energy applications is both timely and significant. With a strong foundation in materials science and a clear trajectory of impactful publications, she is an excellent candidate for the Best Researcher Award.

Prity Yadav | Cell Death Pathway | Best Researcher Award

Published on by Cell Biologist

Ms. Prity Yadav | Cell Death Pathway | Best Researcher Award

Ms. Prity Yadav, UNIVERSITY OF RAJASTHAN, JAIPUR, India

Prity Yadav is a dedicated research scholar at the Department of Zoology, University of Rajasthan, Jaipur, India. Under the guidance of Prof. P.C. Mali, she is pursuing a PhD focused on nanotechnology and reproductive biomedicine. With a strong academic foundation including an M.Sc. in Zoology and CSIR-NET-JRF qualification, she currently receives the Senior Research Fellowship (SRF) from CSIR, Delhi. Her interdisciplinary research combines herbal medicine and nanoscience to develop eco-friendly contraceptive strategies, aiming to revolutionize non-hormonal fertility control. Prity has published 11 research papers in reputed journals indexed in SCI and Scopus, and actively contributes to the scientific community through her work. A member of the Indian Science Congress Association, she is passionate about public health, sustainability, and the responsible use of nanobiotechnology for population control and reproductive health. Her work holds significant promise for advancing global reproductive healthcare through innovative, natural, and non-invasive solutions.

Publication Profile: 

Google Scholar

✅ Strengths for the Award:

  1. Focused and Impactful Research Area
    Prity Yadav’s interdisciplinary research on nanotechnology and reproductive biomedicine is both relevant and innovative, especially in addressing global concerns like non-hormonal contraception, male fertility regulation, and eco-friendly biomedical alternatives.

  2. Consistent Publication Record
    With 11 publications in reputed SCI and Scopus-indexed journals, her research contributions are well-documented and consistently recognized in the academic community.

  3. Research Innovation
    Her work in green synthesis of silver nanoparticles using medicinal plant extracts for antifertility treatments reflects high originality and societal relevance.

  4. Academic Excellence
    She has cleared CSIR-NET-JRF and is currently receiving SRF from CSIR, showing national-level academic competitiveness.

  5. Sustainability and Public Health Focus
    Her projects promote natural, sustainable alternatives to conventional fertility control methods, aligning with public health policy and eco-conscious innovation.

  6. Active Membership in Scientific Community
    Her involvement in organizations such as The Indian Science Congress Association supports her engagement in broader scientific discourse.

🔧 Areas for Improvement:

  1. International Collaborations & Exposure
    Participation in international research collaborations, conferences, or exchange programs would further enrich her global perspective and strengthen her research profile.

  2. Patent Filing and Intellectual Property
    Considering the novelty of her nanoformulations, pursuing patents could enhance the impact and translational value of her work.

  3. Industry Engagement
    Involvement in consultancy or industry-based projects would bridge the gap between lab research and real-world application.

  4. Editorial and Peer Review Roles
    Taking on editorial responsibilities or peer-review contributions would boost her academic service profile.

🎓 Education:

Prity Yadav has a solid academic background in life sciences, specializing in Zoology. She completed her Master of Science (M.Sc.) in Zoology with distinction, focusing on reproductive physiology and applied biology. Demonstrating her academic excellence, she cleared the highly competitive CSIR-NET-JRF examination, qualifying for Junior Research Fellowship and later advancing to Senior Research Fellowship (SRF) funded by CSIR, New Delhi. She is currently enrolled in the PhD program at the University of Rajasthan, Jaipur, under the supervision of Prof. P.C. Mali in the Department of Zoology. Her academic path reflects a consistent focus on animal biology, toxicology, and molecular studies related to fertility and reproduction. Her strong theoretical knowledge, combined with hands-on laboratory training in nanoscience and biomedical research, sets a solid foundation for her innovative research. Prity’s education is a blend of traditional life sciences and modern interdisciplinary tools like nanotechnology and phytomedicine.

🧪 Experience:

Prity Yadav has accumulated significant research experience during her doctoral studies at the University of Rajasthan. With over four years of hands-on laboratory work, she has become proficient in nanoparticle synthesis, in vivo animal experimentation, biochemical analysis, and histopathological techniques. Her research focuses on developing green-synthesized silver nanoparticles using herbal extracts and evaluating their antifertility effects in male rodents. She has co-authored 11 publications in reputable journals and collaborated with fellow researchers on interdisciplinary projects involving herbal pharmacology, nanomedicine, and reproductive biology. While she has no direct industry consultancy experience, her academic research aligns closely with pharmaceutical applications. She frequently presents her findings in national and international conferences and is an active member of the Indian Science Congress Association. Prity’s experience highlights her commitment to scientific rigor, ethical research practices, and a vision for creating sustainable healthcare solutions through biocompatible nanotechnologies.

🔬 Research Focus:

Prity Yadav’s research lies at the intersection of nanotechnology and reproductive biomedicine, with an emphasis on developing herbal-based, non-hormonal antifertility agents. Her work explores the green synthesis of silver nanoparticles using medicinal plant extracts, aiming to enhance bioavailability and targeted delivery of active phytoconstituents. The ultimate goal of her research is to create eco-friendly, reversible male contraceptive methods with minimal side effects. She focuses on evaluating the impact of these nanoparticles on male reproductive systems through in vivo studies using rodent models. Her findings contribute to a deeper understanding of reproductive toxicity, oxidative stress, and fertility regulation mechanisms. This research addresses global challenges such as overpopulation and limited access to safe male contraceptives. Prity’s interdisciplinary approach supports sustainable healthcare by integrating traditional herbal knowledge with modern nanoscience, opening new avenues in contraceptive technology and public health policy.

📚 Publications Top Notes: 

  1. 🌿🔬 Herbal Nanoparticles to Control Fertility and Regulation: A Review

  2. 🧫🔥 Testicular Inflammation in Male Reproductive System

  3. 🍃🧪 Assessment of the Antifertility Potential of Silver Nanoparticles Synthesized Using Pongamia pinnata Leaf Extract in Male Wistar Rats

  4. 🌱📖 Medicinal Plants Potentials of Fertility Control, Antioxidant and Antimicrobial Activities: A Review

  5. 🧬🌿 Potential Antifertility and Antimicrobial Activities of Plants Used in Traditional Medicines: A Review

  6. 💊🦠 Cassia auriculata-Based Silver Nanoparticles: A Novel Approach to Combat Bacterial Infections

  7. 🌾🧠 A Review on Potential Antioxidant, Neuroprotective and Antidepressant Activities of Herbal Medicinal Plants

  8. ⚗️🧍‍♂️ Effects of Silver Nanoparticles of Putranjiva roxburghii on Reproductive Organs in Male Albino Rats

  9. 🌳🧬 Exploring the Impacts of Tecomella undulata Mediated Silver Nanoparticles on Male Rats Fertility and Reproductive Health

  10. 🍀🧫 An In Vitro Antioxidant Potential Analysis of Herbal Silver Nanoparticles Synthesized from Methanolic Leaf Extract of Cassia siamea

🧾 Conclusion:

Based on her scientific contributions, innovative research, and academic merit, Prity Yadav is a highly suitable candidate for the Best Researcher Award. Her work presents a unique and impactful solution to pressing challenges in public health and reproductive medicine. With scope for further growth in collaborative and translational domains, she stands out as a rising researcher making meaningful advances in her field.

Zhi Guo | Stem Cell Research | Best Researcher Award

Published on by Cell Biologist

Prof. Dr Zhi Guo | Stem Cell Research | Best Researcher Award

Prof. Dr Zhi Guo | Department of Hematology, Huazhong University of Science and Technology Union Shenzhen Hospital | China

Dr. Zhi Guo is a distinguished expert in hematology with over 25 years of clinical and academic experience. Currently serving as Director, Academic Leader, Chief Physician, and Professor at the Department of Hematology, Huazhong University of Science and Technology Union Shenzhen Hospital, he has been instrumental in advancing hematologic malignancy treatments in China. With extensive expertise in hematopoietic stem cell transplantation, Dr. Guo has successfully performed more than 1,300 transplant cases. He began his career at the PLA Army General Hospital, serving there for nearly two decades before transitioning to his current role. A prolific researcher, he has authored over 10 peer-reviewed publications and five books, contributing substantially to the understanding of CAR-T therapy, gut microbiota, and transplantation immunology. He is an active member of major national and international hematology associations and plays a vital role in formulating clinical consensus and guidelines in China.

publication profile:

Scopus

Strengths for the Award:

Dr. Zhi Guo exemplifies the qualities of an outstanding medical researcher and clinician. With nearly 25 years of clinical experience in hematology and over 20 years in hematopoietic stem cell transplantation, he stands out as a national leader in this field. His performance of more than 1,300 transplants, along with a strong academic footprint, including 10 SCI-indexed publications in 2024–2025, demonstrates both depth and innovation in his research. He has also contributed to national expert consensus and clinical guidelines, particularly in CAR-T therapy and intestinal microecology. Dr. Guo’s leadership roles across national academic committees and his active membership in the American Society of Hematology further highlight his international impact and collaborative influence.

Areas for Improvement:

While Dr. Guo’s achievements in clinical practice and research are significant, opportunities exist to increase global visibility by expanding his research collaborations internationally and publishing in higher-impact journals beyond regional scopes. Additionally, while five books have been authored, the addition of patents or translational innovations could enhance his profile in the realm of research commercialization and practical medical technologies.

Education :

Dr. Zhi Guo holds a strong academic background in clinical medicine and medical research. He earned his Bachelor’s degree in Medicine from Tongji Medical College in 2000. Subsequently, he pursued his postgraduate medical studies at the Third Military Medical University, completing it in 2007. His academic journey culminated with the attainment of a Doctor of Medicine (MD) degree from Wuhan University of Science and Technology. His education laid a strong foundation in hematology and clinical research methodologies. Each step in his educational path was marked by an emphasis on academic rigor and clinical competence, preparing him for a leadership role in medical science and hematologic research. His multidisciplinary background has enabled him to integrate clinical insights with advanced laboratory-based innovations, contributing to national-level guidelines and the development of cutting-edge CAR-T cell therapies and transplantation techniques.

Experience :

Dr. Zhi Guo brings nearly 25 years of clinical, academic, and leadership experience in the field of hematology. He began his professional journey at the PLA Army General Hospital, where he served from 2000 to 2018. During this period, he honed his clinical and procedural expertise in managing complex hematologic disorders. Since 2018, he has been leading the Department of Hematology at Huazhong University of Science and Technology Union Shenzhen Hospital as Director, Academic Leader, and Chief Physician. His rich experience includes more than 1,300 hematopoietic stem cell transplantations, encompassing autologous, allogeneic, and CAR-T integrated therapies. His leadership extends beyond clinical care, as he also mentors postgraduate medical students and leads multiple national and institutional research projects. Dr. Guo’s practical experience is balanced with his strategic contributions to medical consensus formulation and research-driven policy initiatives in cancer and immune-hematological disorders.

Research Focus :

Dr. Zhi Guo’s research centers on hematologic malignancies and hematopoietic stem cell transplantation, particularly the integration of cellular immunotherapy such as CAR-T cell treatments. His recent work includes pioneering anti-CD19, anti-CD7, and anti-BCMA CAR-T therapies for lymphomas and leukemias. Additionally, he has investigated the interplay between microbiota and immune modulation in transplantation, highlighting the role of gut and oral microbiomes in patient outcomes. His contributions have influenced the development of clinical guidelines for microbiota-related diagnostics and treatments in oncology. With more than 10 high-impact journal publications and ongoing projects in translational medicine, Dr. Guo’s work combines laboratory innovation with patient-centered applications. He has also authored expert consensus documents and national guidelines, helping shape China’s hematology and transplantation protocols. His commitment to interdisciplinary collaboration, clinical innovation, and translational research underscores his leading role in advancing modern hematology.

Publications Top Notes:

  1. 🧬 In vitro validation of anti-CD19 CAR-T cells with LSD1 shRNA for DLBCLFront Immunol, 2025

  2. 🩸 Case of T-ALL treated with chemo + anti-CD7 CAR-T (retroviral vector)Front Immunol, 2025

  3. 👶 Shaping oral/intestinal microbiota & immunity in first 1,000 days of lifeFront Pediatr, 2025

  4. 💩 Fecal microbiota transplantation in acute GVHD treatmentJ Cancer Res Ther, 2024

  5. 🔬 Chinese consensus on gut microecology lab standardsExp Ther Med, 2024

  6. 🧪 2024 Chinese guidelines for intestinal microecology in cancerJ Cancer Res Ther, 2024

  7. 🧫 First MM case treated with ASCT + anti-BCMA CAR-T (retrovirus)Heliyon, 2024

  8. 🧾 Rapid response in relapsed FL to anti-CD19 CAR-T with CMVInt Immunopharmacol, 2024

  9. 🦷 Prognostic impact of oral microbiome in cancer survival – meta-analysisSyst Rev, 2024

  10. 🧍‍⚕️ Expert consensus on gut microbiome & hematopoietic stem cell transplantationClin Transplant, 2024

Conclusion:

In conclusion, Dr. Zhi Guo is highly suitable for the Best Researcher Award. His combination of clinical excellence, academic leadership, and impactful research in hematology and stem cell transplantation positions him among the top contributors in this specialized field. With ongoing research in CAR-T cell therapies, microbiota influence on transplantation, and immuno-oncology, Dr. Guo continues to shape the future of hematologic cancer care. Recognizing his contributions with this award would be both fitting and encouraging for continued innovation in this vital area of medicine.