Hamed Bayesteh | Soil | Best Researcher Award

Assoc Prof Dr. Hamed Bayesteh | Soil | Best Researcher Award

Associate Professor at University of Qom, Iran

Dr. Hamed Bayesteh is an Assistant Professor at the University of Qom, Iran, with extensive experience in geotechnical and marine engineering. With over 19 years in the field, his work spans a diverse array of projects, including marine structures, soil improvement, deep foundations, and underground structures. His role encompasses project management, technical consulting, and academic instruction. Dr. Bayesteh is known for his expertise in soil stabilization methods, design of marine structures, and numerical modeling in geotechnical engineering.

Author Metrics

Google Scholar Profile

Dr. Bayesteh’s work is widely recognized in the field of geotechnical engineering, as reflected in his Google Scholar profile. He has published numerous articles in high-impact journals and has garnered significant citations for his research. His metrics demonstrate a strong influence and contribution to the scientific community, underscoring the impact of his research on both theoretical and practical aspects of geotechnical engineering.

  • Citations: Dr. Bayesteh has accumulated a total of 420 citations for his work. Since 2019, his publications have been cited 369 times, indicating a robust and ongoing relevance of his research in recent years. These citations are a testament to the influence and importance of his contributions to the field.
  • h-index: Dr. Bayesteh’s h-index is 14. This metric means that he has at least 14 publications that have each been cited at least 14 times. The h-index is a measure of both productivity and impact, suggesting that Dr. Bayesteh has a substantial number of impactful publications.
  • i10-index: His i10-index stands at 16, which indicates that he has 16 publications with at least 10 citations each. This metric highlights the number of his works that have been cited frequently, underscoring the sustained interest and relevance of his research.

Education

Dr. Bayesteh’s academic background includes a Ph.D. in Geotechnical Engineering from the University of Tehran (2013), an MSc in Geotechnical Engineering from Bu Ali Sina University (2005), and a BSc in Civil Engineering from Isfahan University of Technology (2003). Additionally, he completed an MBA at the University of Tehran (2014), highlighting his interdisciplinary approach to engineering and management.

Research Focus

Dr. Bayestehā€™s research focuses on various aspects of geotechnical engineering, including soil improvement techniques, marine geotechnics, deep foundations, and numerical methods. His work involves studying the behavior of soils under different conditions, developing new methods for soil stabilization, and improving the design of marine and coastal structures. His recent studies have explored the effects of high salinity on soil behavior, innovative construction methods, and the performance of different soil improvement techniques.

Professional Journey

Dr. Bayestehā€™s professional journey spans over two decades in both academia and industry. He has held key roles such as project manager, technical and engineering manager, and geotechnical engineer. His career includes significant consulting work on various projects, including marine structures, petrochemical facilities, and urban infrastructure. His diverse experience bridges theoretical research and practical applications, demonstrating his broad expertise in the field.

Honors & Awards

Dr. Bayesteh has been recognized for his contributions to the field of geotechnical engineering through various awards and honors. His work is distinguished by its impact on both academic research and practical engineering solutions. While specific awards are not detailed in the provided information, his extensive list of publications and successful project outcomes reflect a high level of professional achievement and recognition.

Publications Noted & Contributions

Dr. Bayesteh has authored and co-authored numerous publications in renowned journals. His notable contributions include research on the performance of cement-stabilized marine clay, numerical simulations of soil behavior, and the impact of high salinity on soil stability. His work has been published in journals such as “Construction and Building Materials,” “Geotechnical and Geological Engineering,” and “Computational Particle Mechanics,” among others.

1. Experimental Investigation of the Bond Strength Between GFRP and Steel Bars and Soil-Cement

  • Authors: Hamed Bayesteh, Ebrahim Safraei, Mohammad Sharifi
  • Journal: Structures
  • Volume: 65
  • Article Number: 106761
  • Year: 2024

Summary: This study explores the bond strength between Glass Fiber Reinforced Polymer (GFRP) bars and steel bars embedded in soil-cement mixtures. The research provides experimental data on the performance and interactions between these materials, which is crucial for designing reinforced structures that use soil-cement as a construction medium.

2. Effect of Particle Size Ratio and Fines Content on Drained/Undrained Behavior of Binary Granular Soil According to Confining Pressure and Packing Density: A DEM Simulation

  • Authors: Fariborz Vahidi-Nia, Hamed Bayesteh, Mohammad Khodaparast
  • Journal: Computational Particle Mechanics
  • Volume: 11 (1)
  • Pages: 141-167
  • Year: 2024

Summary: This publication uses Discrete Element Method (DEM) simulations to investigate how particle size ratio and fines content affect the behavior of binary granular soils under different confining pressures and packing densities. The study contributes to understanding soil mechanics and improves predictions of soil behavior in various geotechnical applications.

3. Innovative Top-Down Construction Method with a Sequential Peripheral Wall

  • Authors: Mohammad Rojhani, Hamed Bayesteh
  • Journal: Geotechnical and Geological Engineering
  • Volume: 41 (3)
  • Pages: 1777-1799
  • Year: 2023

Summary: This paper presents a new Top-Down construction method that incorporates a sequential peripheral wall. The method aims to improve efficiency and stability during construction, particularly in urban environments where space is limited. The innovative approach addresses common challenges associated with Top-Down construction.

4. A New Failure Criteria for Hollow-Bar Micropile Based on Full-Scale Static Load Tests

  • Authors: Mohammad Fakharnia, Hamed Bayesteh
  • Journal: Amirkabir Journal of Civil Engineering
  • Volume: 52 (4)
  • Pages: 919-934
  • Year: 2020

Summary: This study introduces a new failure criterion for hollow-bar micropiles, developed through full-scale static load tests. The proposed criterion enhances the understanding of micropile behavior under load, which is essential for the design and safety of deep foundation systems.

5. The Role of Fines Content and Particle Size Ratio on the Load-Bearing Structure of Binary Granular Soil: A Micromechanical Approach

  • Authors: Fariborz Vahidi-Nia, Hamed Bayesteh, Mohammad Khodaparast
  • Journal: Computational Particle Mechanics
  • Year: 2024 (forthcoming)

Summary: This forthcoming paper examines how fines content and particle size ratio influence the load-bearing capacity of binary granular soils using a micromechanical approach. The research provides insights into the granular soil’s structural behavior, which is critical for applications in geotechnical engineering.

Research Timeline

Dr. Bayesteh’s research timeline reflects a progression from early studies on soil behavior and dispersivity to more recent investigations into advanced soil improvement techniques and numerical simulations. His research has evolved to address contemporary challenges in geotechnical engineering, such as the impact of environmental conditions on soil stability and innovative construction methods.

Collaborations and Projects

Dr. Bayesteh has collaborated with various organizations and companies on significant projects, including the design and improvement of marine structures, soil stabilization for petrochemical facilities, and urban excavation projects. His collaborations with entities such as the Port & Maritime Organization (PMO), Asian Pacific, and various petrochemical companies highlight his role in advancing practical engineering solutions and enhancing infrastructure development.

Strengths of Dr. Hamed Bayesteh’s Research and Best Researcher Award:

  1. High Citation Impact: With a total of 420 citations and a robust recent citation rate, Dr. Bayesteh’s research is highly influential in geotechnical engineering. His h-index of 14 and i10-index of 16 reflect both significant productivity and impact, demonstrating the relevance and importance of his work in advancing the field.
  2. Diverse Research Focus: Dr. Bayesteh’s research covers a wide range of topics within geotechnical engineering, including soil stabilization, marine structures, and numerical modeling. This diversity showcases his ability to address various aspects of the field, contributing valuable insights to both theoretical and practical applications.
  3. Innovative Contributions: His publications highlight contributions to innovative methods and techniques, such as the new Top-Down construction method and advanced soil improvement techniques. These contributions not only advance academic knowledge but also offer practical solutions to engineering challenges.
  4. Cross-Disciplinary Expertise: Dr. Bayestehā€™s background in both geotechnical engineering and business management (MBA) enhances his ability to manage projects effectively and integrate engineering solutions with practical management strategies, benefiting both academic and industrial applications.
  5. Extensive Professional Experience: With over 19 years in the field, including roles in project management and technical consulting, Dr. Bayestehā€™s extensive experience enriches his research. His practical insights and hands-on approach to solving real-world problems strengthen the impact and relevance of his research.

Areas for Improvement:

  1. Increased Visibility in Broader Academic Circles: While Dr. Bayesteh has made significant contributions to geotechnical engineering, expanding his visibility in interdisciplinary and international academic circles could further enhance the reach and impact of his work.
  2. Collaboration with Emerging Technologies: Embracing newer technologies such as artificial intelligence or machine learning in his research could open new avenues for innovation and enhance the analytical depth of his studies.
  3. Enhanced Outreach and Public Engagement: Increasing efforts to communicate his research findings to a broader audience, including non-specialists and industry stakeholders, could further bridge the gap between academia and practical applications.
  4. Diverse Publication Venues: Expanding the range of journals and conferences where his research is published could enhance the dissemination and impact of his work. Exploring high-impact journals outside his primary field might attract a wider audience.
  5. Focus on Emerging Environmental and Sustainability Issues: Integrating more research on sustainable practices and environmental impact in geotechnical engineering could address pressing global challenges and enhance the societal relevance of his work.

Conclusion:

Dr. Hamed Bayestehā€™s recognition as a Best Researcher highlights his substantial contributions to geotechnical engineering, underscored by his high citation impact, innovative research, and extensive professional experience. His diverse research focus and ability to address practical engineering challenges reinforce his stature in the field. However, there are opportunities for further growth, such as increasing visibility in broader academic circles, incorporating emerging technologies, and enhancing outreach efforts. Addressing these areas could amplify the impact of his research and strengthen his role as a leader in advancing geotechnical engineering.

Joel Okpoghono | Clinical Biochemistry | Excellence in Research

Dr. Joel Okpoghono | Clinical Biochemistry | Excellence in Research

Doctorate at Delta state University of Science and Technology, Ozoro, Nigeria

Dr. Okpoghono Joel is a distinguished biochemist with a specialized focus on Nutritional and Clinical Biochemistry as well as Toxicology. Born on May 11, 1982, in Ikogosi Ekiti, Nigeria, he hails from Isoko South in Delta State. With a robust educational background from Delta State University and relevant professional training in computer science, Dr. Joel has established a notable career in the field of biochemistry. His academic journey and research contributions underscore a commitment to advancing knowledge in nutritional and clinical biochemistry.

Author Metrics

Scopus Profile

ORCID Profile

Google Scholar Profile

Dr. Joelā€™s scholarly work has been recognized with a citation count of 46, reflecting the impact and relevance of his research in the field. He has authored 25 documents, contributing significantly to the scientific community. His h-index is 5, indicating a solid number of citations for his most cited publications. These metrics underscore his influence and the quality of his research outputs.

Education

Dr. Joelā€™s academic credentials are grounded in a comprehensive study of biochemistry. He earned his Ph.D. in Biochemistry with a focus on Nutritional, Clinical Biochemistry, and Toxicology from Delta State University of Science and Technology, Ozoro, in 2018. Prior to this, he completed his M.Sc. in Biochemistry at Delta State University, Abraka, in 2013, and his B.Sc. (Hons) in Biochemistry in 2006 from the same institution. Additionally, he holds a Certificate in Computer Appreciation from Simek Computer Training, emphasizing his proficiency in technological tools relevant to his research.

Research Focus

Dr. Joelā€™s research is centered on Nutritional Biochemistry, Clinical Biochemistry, and Toxicology. His work in Nutritional Biochemistry explores the interplay between diet and health, focusing on how nutritional components affect biochemical processes. In Clinical Biochemistry, he investigates the biochemical basis of diseases and disorders, aiming to enhance diagnostic and therapeutic strategies. His research in Toxicology addresses the impact of toxic substances on biological systems, contributing to the understanding of environmental and clinical toxicants.

Professional Journey

Dr. Joelā€™s professional journey has been marked by significant academic and research achievements. He has pursued advanced studies and research in biochemistry, culminating in a Ph.D. that highlights his expertise in specialized areas of the field. His career reflects a dedication to advancing scientific knowledge and applying it to practical challenges in health and disease.

Honors & Awards

Dr. Joel has received recognition for his academic and research achievements. These honors reflect his contributions to the field of biochemistry and his impact on scientific knowledge. The specifics of these awards may include academic scholarships, research grants, or professional accolades that highlight his excellence in biochemistry.

Publications Noted & Contributions

Dr. Joelā€™s publications have made a notable impact in his field, with 25 documents cited 46 times. His research contributions are well-regarded, with several publications that advance understanding in Nutritional and Clinical Biochemistry and Toxicology. His work has been published in reputable journals and has contributed to the scientific discourse in these areas.

1. Influence of Kaempferol Against Garri Meal Tainted with Vacuum Gas Oil Induced Nephro- and Neurotoxicity

  • Journal: Food Chemistry Advances
  • Publication Date: December 2024
  • DOI: 10.1016/j.focha.2024.100794
  • Contributors: Joel Okpoghono, Busade Adebayo Agbetuyi, Toritseju Eyide, Innocent Onyesom
  • Summary: This study investigates the protective effects of kaempferol against nephro- and neurotoxicity induced by garri meal contaminated with vacuum gas oil. The research contributes to understanding how natural compounds can mitigate the harmful effects of environmental toxins on kidney and brain health.

2. Assessment of Vitamins and Minerals of Rats Fed with Plantain-Maize Pudding Prepared Using Edible Plant Leaves and Metallic Plates

  • Journal: Food Research
  • Publication Date: July 19, 2024
  • DOI: 10.26656/fr.2017.8(4).359
  • Contributors: J. Okpoghono, U.B. Igue, F.E. Isoje, S.U. Okom, A.A. Seigha, M. Erorun
  • Summary: This article evaluates the nutritional quality of plantain-maize pudding prepared with edible plant leaves and metallic plates. The study assesses the vitamin and mineral content, providing insights into how different preparation methods impact the nutritional value of food.

3. Natural Polyphenols: A Protective Approach to Reduce Colorectal Cancer

  • Journal: Heliyon
  • Publication Date: June 2024
  • DOI: 10.1016/j.heliyon.2024.e32390
  • Contributors: Joel Okpoghono, Endurance F. Isoje, Ufuoma A. Igbuku, Ovigueroye Ekayoda, Godson O. Omoike, Treasure O. Adonor, Udoka B. Igue, Solomon U. Okom, Faith O. Ovowa, Queen O. Stephen-Onojedje et al.
  • Summary: This review article explores the role of natural polyphenols in the prevention of colorectal cancer. It discusses various polyphenolic compounds and their mechanisms of action in reducing cancer risk, highlighting their potential as dietary interventions.

4. Anthropometric Indices and Prevalence of Iron Deficiency Anaemia Among School Children in Delta State, Nigeria: An Intervention Study

  • Journal: Acta Medica Bulgarica
  • Publication Date: June 1, 2024
  • DOI: 10.2478/amb-2024-0018
  • Contributors: J. E. Moyegbone, J. Okpoghono, E. U. Nwose, A. Clarke, C. C. Ofili, J. O. Odoko, E. A. Agege
  • Summary: This intervention study examines the relationship between anthropometric measurements and the prevalence of iron deficiency anemia among school children in Delta State, Nigeria. The research provides data on the effectiveness of nutritional interventions in addressing anemia in children.

5. Anti-Lipidemic and Protein Restoration Potential of Monodora Myristica (Gaertn.) in Rats Fed with Cassava Containing Crude Oil

  • Journal: Foods and Raw Materials
  • Publication Date: January 30, 2024
  • DOI: 10.21603/2308-4057-2024-2-602
  • Contributors: Joel Okpoghono, Jonah Kanayo Ukperegbulem, Udoka Bessie Igue
  • Summary: This study evaluates the anti-lipidemic and protein restoration effects of Monodora myristica in rats exposed to cassava contaminated with crude oil. It highlights the potential of this plant in mitigating lipid disorders and restoring protein levels in toxic conditions.

Research Timeline

Dr. Joelā€™s research timeline reflects his academic and professional development. Key milestones include earning his B.Sc. in 2006, followed by his M.Sc. in 2013, and completing his Ph.D. in 2018. His research activities during and after these academic achievements have contributed to his expertise and impact in biochemistry. The timeline also includes the publication of significant research papers and contributions to scientific knowledge.

Collaborations and Projects

Throughout his career, Dr. Joel has engaged in various collaborations and projects that enhance his research and professional network. These collaborations may involve joint research efforts with other scientists, participation in interdisciplinary projects, and contributions to research initiatives that align with his expertise in biochemistry. His involvement in these projects highlights his commitment to advancing science through collective efforts.

Strengths of Dr. Joel Okpoghonoā€™s Research Excellence

  1. Focused Expertise: Dr. Joel Okpoghono has a well-defined research focus in Nutritional Biochemistry, Clinical Biochemistry, and Toxicology. His expertise in these areas is evident from his publications and research contributions, which address crucial aspects of health and disease.
  2. Impactful Publications: With a total of 25 documents and 46 citations, Dr. Joel’s research has made a tangible impact in his field. His publications cover diverse topics, from the protective effects of natural compounds against toxins to the role of diet in disease prevention, demonstrating the relevance of his work.
  3. Recent Research Innovations: His recent studies, such as the evaluation of kaempferolā€™s protective effects against nephro- and neurotoxicity and the role of natural polyphenols in colorectal cancer prevention, reflect a commitment to exploring novel and impactful research questions.
  4. Interdisciplinary Approach: Dr. Joelā€™s integration of biochemistry with other fields, such as computer science (evidenced by his Certificate in Computer Appreciation), enhances his research methodology and data analysis capabilities, contributing to the robustness of his research findings.
  5. Strong Academic Foundation: Dr. Joelā€™s educational background, culminating in a Ph.D. focused on specialized areas of biochemistry, provides a solid foundation for his research. His academic progression from B.Sc. to M.Sc. and Ph.D. highlights his dedication and growth in the field.

Areas for Improvement

  1. Increased Citation Metrics: While Dr. Joel has a respectable citation count, increasing his h-index and citation metrics could further reflect the impact and recognition of his work. Strategies such as broader dissemination and collaboration could enhance visibility.
  2. Broader Research Impact: Expanding research topics or exploring interdisciplinary applications of his biochemistry expertise could attract wider interest and address broader scientific and public health issues.
  3. Enhanced Collaboration: Although Dr. Joel has engaged in various collaborations, further expanding his network to include international researchers and institutions could bring new perspectives and opportunities to his work.
  4. Funding and Grants: Securing more research grants and funding could support larger-scale studies and innovative projects. Actively pursuing grants and partnerships with funding agencies could provide the necessary resources for impactful research.
  5. Public Engagement and Outreach: Increasing efforts in public science communication and outreach could enhance the societal impact of his research. Engaging with broader audiences through public lectures, media, and community-based initiatives could raise awareness of his work.

Conclusion

Dr. Joel Okpoghono is a distinguished biochemist with a robust record of research in Nutritional and Clinical Biochemistry and Toxicology. His recent studies and innovative approaches underscore his commitment to advancing scientific knowledge and addressing pressing health issues. While his research has made significant contributions to the field, there are opportunities for growth, including improving citation metrics, expanding research impact, and increasing public engagement. By addressing these areas for improvement, Dr. Joel can further enhance his influence and continue to make valuable contributions to the field of biochemistry.

Mohamed attia | Analytical Chemistry | Best Researcher Award

Prof Dr. Mohamed attia | Analytical Chemistry | Best Researcher Award

Ā Professor at Ain Shams University, Egypt

Prof. Dr. Mohamed Said Attia is a leading analytical chemist and professor at Ain Shams University, where he heads a research group focused on the early diagnosis of diseases using nano-optical sensors. He is also the Director of the Chemical and Biochemical Studies and Consultations Unit. His academic career, marked by a PhD from Ain Shams University and a professorship awarded in 2017, underscores his significant contributions to the fields of analytical chemistry and nanotechnology. His innovative research and extensive publications highlight his impact on cancer diagnosis and environmental monitoring.

Author Metrics

Scopus Profile

ORCID Profile

Google Scholar Profile

Prof. Attia has achieved an h-index of 29, reflecting his substantial academic impact through both the volume and citation of his work. His prolific output includes 112 papers and 10 books, indicating his extensive influence in analytical chemistry and nanotechnology. These metrics underscore his prominence and contribution to advancing scientific knowledge in his field.

  • Citations: 1,534 citations from 824 documents
  • Documents: 104
  • h-index: 28

Education

Prof. Attia earned his PhD in analytical chemistry from Ain Shams University in 2006. This advanced degree provided a solid foundation for his subsequent research and academic career, leading to his elevation to a full professorship in 2017. His educational background has been crucial in shaping his expertise and achievements in analytical chemistry.

Research Focus

Prof. Attia’s research primarily involves developing and applying nano-optical sensors for early disease diagnosis, with a particular focus on cancer detection. His work also encompasses analytical photochemistry, nano-photochemistry, and the creation of nano photocatalysts. This focus aims to improve diagnostic techniques and environmental monitoring through advanced sensor technologies.

Professional Journey

Prof. Attia’s professional trajectory includes significant roles in research and academia. He began his career as a lecturer and progressed to a full professor by 2017. Throughout his career, he has led impactful research projects, directed the Chemical and Biochemical Studies and Consultations Unit, and contributed to practical applications in medicine and industry, establishing himself as a leading figure in his field.

Honors & Awards

Prof. Attia has received several prestigious awards recognizing his research contributions. Notably, his project on the green synthesis of magnetic iron oxide nanoparticles won the “2019 Green Chemistry for Life Science” award from PhosAgro/UNESCO/IUPAC. This accolade highlights his outstanding work in green chemistry and his global recognition for advancing scientific and environmental solutions.

Publications Noted & Contributions

Prof. Attia has published extensively, including 10 books and over 112 papers in peer-reviewed journals. His work covers a broad range of topics such as nano-optical sensors and analytical photochemistry. His publications are well-cited and have significantly contributed to the advancement of knowledge in disease diagnostics and environmental applications.

“Polymer-Based Terbium Complex as a Fluorescent Probe for Cancer Antigen 125 Detection: A Promising Tool for Early Diagnosis of Ovarian Cancer”

  • Journal: ACS Omega
  • Publication Date: June 11, 2024
  • DOI: 10.1021/acsomega.4c01814
  • Contributors: Magda M. Mohamed, Hisham Gamal, Akram El-Didamony, Ahmed O. Youssef, Esraa Elshahat, Ekram H. Mohamed, Mohamed S. Attia

“Highly selective optical sensor N/S-doped carbon quantum dots (CQDs) for the assessment of human chorionic gonadotropin Ī²-hCG in the serum of breast and prostate cancer patients”

  • Journal: RSC Advances
  • Publication Date: 2023
  • DOI: 10.1039/D3RA01570J
  • Contributors: Yasmeen M. AlZahrani, Salha Alharthi, Hind A. AlGhamdi, A. O. Youssef, Shahenda S. Ahmed, Ekram H. Mohamed, Safwat A. Mahmoud, Mohamed S. Attia

“Novel sensor for the determination of CA 15-3 in serum of breast cancer patients based on Fe-gallic acid complex doped in modified cellulose polymer thin films”

  • Journal: RSC Advances
  • Publication Date: 2023
  • DOI: 10.1039/D3RA90086J
  • WOSUID: WOS:001156979600001
  • Contributors: Hind A. AlGhamdi, Yasmeen M. AlZahrani, Salha Alharthi, Mohamed S. Mohy-Eldin, Ekram H. Mohamed, Sheta M. Sheta, Said M. El-Sheikh, Safwat A. Mahmoud, Mohamed S. Attia

“Novel sensor for the determination of CA 15-3 in serum of breast cancer patients based on Feā€“gallic acid complex doped in modified cellulose polymer thin films”

  • Journal: RSC Advances
  • Publication Date: 2023
  • DOI: 10.1039/D3RA02495D
  • Contributors: Hind A. AlGhamdi, Yasmeen M. AlZahrani, Salha Alharthi, Mohamed S. Mohy-Eldin, Ekram H. Mohamed, Safwat A. Mahmoud, Mohamed S. Attia

“SiO2/Zn0.4Co0.6Fe2O4 aerogel: an efficient and reusable superparamagnetic adsorbent for oily water remediation”

  • Journal: RSC Advances
  • Publication Date: 2023
  • DOI: 10.1039/D3RA03570K
  • Contributors: Fagr A. Shehata, Amer S. El-Kalliny, Mohamed S. Attia, Tarek A. Gad-Allah

Research Timeline

Prof. Attiaā€™s research timeline highlights his significant contributions across various projects. From 2003 to 2005, he worked on the AQUACAT Project, which focused on photo disinfection of water. Between 2006 and 2008, he conducted research on photovoltaics utilizing Polymer/Quantum Dot Composites. The POWESOL Project from 2007 to 2009 explored mechanical power generation using solar energy. In 2015, his research centered on the early diagnosis of ovarian cancer through nano-optical sensors. His 2019 project, recognized with an award, involved the green synthesis of magnetic nanoparticles. Currently, in 2023, he is engaged in ongoing research on biosensors for detecting MRSA in dairy products.

Collaborations and Projects

Prof. Attiaā€™s collaborations span several high-impact international projects. The AQUACAT Project, in partnership with European and North African teams, focused on water photo disinfection. The POWESOL Project aimed at advancing solar thermodynamic power generation. His work with King Abdul-Aziz University (KAU) involved pioneering early cancer diagnosis using nano-optical sensors. Additionally, the PhosAgro/UNESCO/IUPAC Grant supported his research on green chemistry and nanoparticle synthesis. These collaborations underscore his dedication to advancing scientific knowledge through global partnerships and innovative research.

Strengths of the Best Researcher Award

  1. Innovative Research Focus: Prof. Dr. Mohamed Attia’s award-winning research on nano-optical sensors for early disease diagnosis, particularly cancer detection, showcases cutting-edge innovation. This focus on developing advanced diagnostic tools demonstrates his commitment to addressing critical healthcare challenges and advancing the field of analytical chemistry.
  2. Global Recognition and Impact: The recognition through the “2019 Green Chemistry for Life Science” award highlights Prof. Attia’s global impact on green chemistry. His work on green synthesis of magnetic iron oxide nanoparticles is acknowledged internationally, reflecting the significant contributions he has made to both scientific and environmental solutions.
  3. Extensive Publications and Citations: Prof. Attia’s impressive record of 112 papers and 10 books, coupled with an h-index of 29, signifies his substantial influence in the field. The high citation count of 1,534 further underscores the relevance and impact of his research.
  4. Diverse Research Projects: The breadth of Prof. Attia’s research, including projects on photovoltaics, mechanical power generation, and biosensors, illustrates his versatility and ability to tackle various scientific challenges. This diversity enhances his reputation as a leading researcher in analytical chemistry and nanotechnology.
  5. Strong Collaborative Network: His involvement in international projects and collaborations, such as AQUACAT and POWESOL, showcases his ability to work effectively with global teams. These collaborations not only enhance the scope of his research but also contribute to advancements in scientific knowledge through cross-border partnerships.

Areas for Improvement

  1. Publication Consistency: While Prof. Attia has a substantial number of publications, maintaining consistency in publication frequency and addressing potential gaps in research themes could further strengthen his academic profile. This might involve exploring emerging topics or gaps in current research.
  2. Expansion of Research Applications: While his current focus is on cancer diagnosis and environmental monitoring, expanding research applications to other critical areas, such as infectious diseases or agricultural analytics, could diversify the impact of his work and open new avenues for innovation.
  3. Enhanced Outreach and Dissemination: Increasing efforts in outreach and dissemination of research findings, particularly through public engagement or media, could enhance the visibility and societal impact of his work. This could involve organizing public lectures, workshops, or participating in science communication initiatives.
  4. Interdisciplinary Collaboration: Although Prof. Attia has collaborated internationally, further interdisciplinary collaborations with fields such as biomedical engineering, data science, or artificial intelligence could provide new insights and enhance the applicability of his research in different contexts.
  5. Grant Acquisition and Funding: Securing additional grants and funding for new research projects can help support and expand ongoing work. Exploring new funding opportunities and fostering relationships with potential sponsors or industry partners could bolster research capabilities and resources.

Conclusion

Prof. Dr. Mohamed Attia’s recognition as a leading researcher in analytical chemistry is well-deserved, reflecting his innovative research, global impact, and extensive contributions to the field. His award-winning work, notable publications, and collaborative projects underscore his prominence in advancing disease diagnosis and environmental solutions. To further enhance his research impact, focusing on consistent publication, expanding research applications, improving outreach, fostering interdisciplinary collaborations, and securing additional funding could provide valuable opportunities for growth and continued excellence. Prof. Attia’s ongoing dedication and achievements position him as a pivotal figure in his field, with a promising trajectory for future advancements.

Marina Vesovic | Pharmaceutical chemistry | Medical Chemistry Award

Prof Dr. Marina Vesovic | Pharmaceutical chemistry | Medical Chemistry Award

Professor at Faculty of Medical Sciences Serbia

Prof. Dr. Marina Vesovic is an Associate Professor in the Department of Pharmacy at the Faculty of Medical Sciences, University of Kragujevac. Elected to her current position in June 2023, she specializes in Pharmaceutical Chemistry. Her research focuses on the synthesis, modeling, and evaluation of organic compounds and metal complexes, particularly in relation to their anti-inflammatory, antioxidant, and cytotoxic activities.

Author Metrics

Scopus Profile

  • Citations: 13 citations across 12 documents
  • h-index: 2 (This index measures both the productivity and citation impact of the researcherā€™s publications.)

Research Documents and Impact

Number of Documents: 5
Citations by Document: Reflects the impact and relevance of each published work.

Education

Prof. Vesovicā€™s educational background includes advanced studies in Pharmaceutical Chemistry, which laid the foundation for her expertise and ongoing research in this field. Specific details about her degrees and institutions are not provided, but her role as an associate professor indicates a strong academic background.

Research Focus

Her research centers on medicinal chemistry, pharmaceutical chemistry, and bioinorganic chemistry. She investigates the synthesis and biological activities of organic compounds and metal complexes, focusing on their therapeutic potential and biochemical interactions.

Professional Journey

Prof. Vesovic’s professional journey includes her recent promotion to Associate Professor in 2023, her leadership in various research projects, and her active participation in advancing the field of pharmaceutical chemistry. She has mentored graduate students and contributed to significant research projects in her domain.

Honors & Awards

The bio does not mention specific honors or awards, but Prof. Vesovicā€™s significant contributions to research and education, including her role in various high-impact projects and publications, highlight her esteemed position in her field.

Publications Noted & Contributions

Prof. Vesovic has published extensively, with 18 articles in M20 category journals, 32 in M30, 10 in M50, and 17 in M60. Her notable contributions include a textbook titled “Pharmaceutical Chemistry 1 – Selected Chapters” and numerous research articles detailing her work on pharmaceutical compounds.

Indomethacin Derivatives as Potential Anticancer Agents – Daybreak of New Epoch

Authors: Gogic, A., Vesovic, M., Nedeljkovic, N., Zdravkovic, N., Zivanovic, A.
Journal: ChemistrySelect, 2024, 9(30), e202402050
Citations: 0
Summary: This article explores the potential of indomethacin derivatives as anticancer agents. It presents a detailed study on the synthesis and evaluation of these derivatives, focusing on their anticancer properties. The research aims to offer new insights into drug development for cancer treatment.

Design of Vonoprazan Pyrazole Derivatives as Potential Reversible Inhibitors of Gastric Proton Pump: An In Silico Molecular Docking Study

Authors: Karović, M., Nikolić, B., Nedeljković, N., Vesović, M., Nikolić, M.
Journal: Acta Facultatis Medicae Naissensis, 2024, 41(1), pp. 53ā€“79
Citations: 0
Summary: This article employs in silico molecular docking to design pyrazole derivatives of vonoprazan as potential reversible inhibitors of the gastric proton pump. It offers a computational approach to drug design, aiming to enhance the efficacy of treatments for gastric acid-related disorders.

Synthesis, Characterization, and Investigation of Anti-Inflammatory and Cytotoxic Activities of Novel Thiourea Derivatives of Naproxen

Authors: Nedeljković, N., Nikolić, M., Čanović, P., Vujić, Z., Dobričić, V.
Journal: Pharmaceutics, 2024, 16(1), 1
Citations: 3
Summary: This paper details the synthesis and characterization of novel thiourea derivatives of naproxen, focusing on their anti-inflammatory and cytotoxic activities. The study provides valuable data on these compounds’ potential therapeutic applications and biological effectiveness.

Investigation of the Interaction Between S-Isoalkyl Derivatives of Thiosalicylic Acid and Human Serum Albumin

Authors: Vesović, M., Jelić, R., Nikolić, M., Kljun, J., Tomović, D.
Journal: Journal of Biomolecular Structure and Dynamics, 2024
Citations: 0
Summary: This research investigates how S-isoalkyl derivatives of thiosalicylic acid interact with human serum albumin. The study highlights the binding specificity and potential implications for drug delivery and design.

Synthesis and Investigation of Anti-Inflammatory Activity of New Thiourea Derivatives of Naproxen

Authors: Nedeljković, N., Dobričić, V., BoÅ”ković, J., Vujić, Z., Nikolić, M.
Journal: Pharmaceuticals, 2023, 16(5), 666
Citations: 10
Summary: This article focuses on the synthesis and anti-inflammatory activity of new thiourea derivatives of naproxen. It provides insights into how these new compounds might improve treatment for inflammatory conditions and their potential benefits over existing drugs.

Research Timeline

Ongoing projects include investigations into the synthesis and biological properties of organic and metal complex compounds, with a focus on anti-inflammatory and antioxidant activities. Her recent research efforts span from 2023 to the present, continuing to build on her previous work.

Collaborations and Projects

Prof. Vesovic is involved in several research projects funded by the Ministry of Education, Science, and Technological Development. Her projects include the synthesis and characterization of new drug derivatives, and she is a member of professional societies such as the Serbian Crystallographic Society and the Serbian Society for Immunology, Molecular Oncology, and Regenerative Medicine.

Strengths of Prof. Dr. Marina Vesovic for the Medical Chemistry Award

  1. Research Contributions: Prof. Vesovic’s research focuses on significant areas of pharmaceutical chemistry, including anti-inflammatory, antioxidant, and cytotoxic activities. Her work on indomethacin derivatives, pyrazole derivatives of vonoprazan, and novel thiourea derivatives of naproxen illustrates her commitment to advancing drug development and therapeutic applications.
  2. Publication Record: Her extensive publication record, including articles in high-impact journals like ChemistrySelect and Pharmaceutics, demonstrates a strong and active research presence. Notably, her contributions to understanding drug mechanisms and interactions highlight her expertise.
  3. Innovative Research: Prof. Vesovic’s research employs cutting-edge methods such as in silico molecular docking and detailed biochemical investigations. Her studies into drug interactions with human serum albumin and the development of new drug derivatives show a forward-thinking approach to pharmaceutical chemistry.
  4. Educational and Professional Impact: As an Associate Professor at the Faculty of Medical Sciences, University of Kragujevac, Prof. Vesovic plays a vital role in educating the next generation of pharmaceutical chemists. Her leadership in research projects and mentorship of graduate students underscores her influence in the field.
  5. Active Research Projects: Her ongoing research projects funded by reputable organizations and her involvement in professional societies demonstrate her dedication and engagement with the broader scientific community. These efforts contribute to both theoretical and practical advancements in pharmaceutical chemistry.

Areas for Improvement

  1. Citation Impact: Despite a solid publication record, Prof. Vesovic’s citation metrics are relatively modest. Increasing the visibility and impact of her research could involve strategic collaborations and high-profile publications to enhance citation counts.
  2. Research Visibility: While her research is highly relevant, increasing its visibility through conference presentations, media engagement, or collaborative projects with international researchers could further elevate her profile in the field.
  3. Grant Funding: Securing additional research funding or collaborating on larger, multi-institutional grants could provide more resources for her projects and expand the scope of her research.
  4. Publication Diversity: Expanding the range of journals where her work is published, including higher-impact journals or interdisciplinary platforms, might improve both the reach and influence of her research.
  5. Award and Recognition: Gaining recognition through prestigious awards or honors could further validate her contributions to the field. Actively pursuing such accolades or nominations could enhance her professional standing.

Conclusion

Prof. Dr. Marina Vesovic is a promising candidate for the Medical Chemistry Award due to her significant research contributions, extensive publication record, and innovative approaches to drug development. Her work demonstrates a deep understanding of pharmaceutical chemistry and its applications in medicine. By addressing areas such as increasing research visibility and enhancing citation impact, she could further strengthen her candidacy and contribute even more significantly to the field of pharmaceutical chemistry.

Seda Nur Topkaya | Biosensors | Best Researcher Award

Prof Dr. Seda Nur Topkaya | Biosensors | Best Researcher Award

Professor at Izmir Katip Ceelbi University, Turkey

Dr. Seda Nur Topkaya Cetin is a distinguished Professor and Chair of the Basic Pharmaceutical Sciences Department at Izmir Katip Celebi University, where she also leads the Department of Analytical Chemistry. Her extensive academic and research career is centered around analytical chemistry, with a focus on electrochemistry, biosensor development, and nanomaterials. With a Ph.D. from Ege University and significant research experience in renowned institutions such as Harvard Medical School and the Max Planck Institute, Dr. Topkaya Cetin has made substantial contributions to the fields of molecular diagnostics and biosensing technologies.

Author Metrics

Scopus Profile

ORCID Profile

Dr. Topkaya Cetin has published extensively in peer-reviewed journals and book chapters, contributing significantly to the fields of analytical chemistry and biosensors. Her research articles have been widely cited, reflecting her influence and impact on her areas of expertise. She serves as a reviewer and editorial board member for several prominent scientific journals, further underscoring her role as a leading figure in her field.Seda Nur Topkaya, a researcher affiliated with Ä°zmir KĆ¢tip Ƈelebi Ɯniversitesi in Turkey. Her Scopus Author Identifier and ORCID profile suggest she has a notable academic presence, with 1,613 citations across 1,514 documents and an h-index of 18.

Education

Dr. Topkaya Cetin obtained her Ph.D. in Analytical Chemistry with a focus on Electrochemistry from Ege University in 2013. She completed her M.Sc. in the same field at Ege University in 2009, following her undergraduate studies in Pharmacy at the same institution. Her education was complemented by international research experiences, including stints at Harvard Medical School, Joseph Fourier University, and the Max Planck Institute, where she expanded her expertise in tissue engineering, nanomaterials, and biosensing technologies.

Research Focus

Dr. Topkaya Cetinā€™s research primarily focuses on the development and optimization of electrochemical biosensors for medical diagnostics. Her work includes the label-free detection of gene hypermethylation and single-point mutations related to cancer and myeloproliferative disorders. Additionally, she investigates miRNA sensing and miRNA-protein interactions using both labeled and label-free strategies. Her research also explores nanomaterials and their applications in biosensing, contributing to advancements in molecular diagnostics and personalized medicine.

Professional Journey

Dr. Topkaya Cetin’s professional journey includes significant roles at both Ege University and Izmir Katip Celebi University. She began as a Research and Teaching Assistant at Ege University, advancing through the ranks to become an Assistant Professor and later an Associate Professor. Since 2017, she has held leadership positions at Izmir Katip Celebi University, including Head of the Analytical Chemistry Department and the Basic Pharmaceutical Sciences Department. Her career reflects a dedication to both teaching and research, with substantial contributions to the advancement of pharmaceutical sciences.

Honors & Awards

Dr. Topkaya Cetin has received numerous accolades for her research and contributions to science. Notable awards include the Best Poster Competition Third Prize at FOTONÄ°K 2022, the Encouragement Award from the Turkish Pharmacistsā€™ Association in 2017, and the prestigious 65th Lindau Nobel Laureate Meeting participation in 2015. She has also been recognized with several scholarships and fellowships, including the DAAD Scholarship for Academics and the Turkish Council of Higher Education International Research Fellowship.

Publications Noted & Contributions

Dr. Topkaya Cetin has published extensively, with her research appearing in both national peer-reviewed journals and international book chapters. Key publications include works on biosensor applications in beverages, cancer detection, and electrochemical biosensors for nucleic acid analysis. Her contributions are noted for advancing the understanding and application of biosensing technologies, particularly in the context of disease diagnosis and environmental monitoring.

“Electrochemical Profiling of Natural Furanocoumarins: DNA Interaction Dynamics of Oxypeucedanin and Prantschimgin”

  • Journal: ADMET and DMPK
  • Year: 2024
  • DOI: 10.5599/ADMET.2199
  • Details: This study explores the electrochemical interactions of furanocoumarins with DNA, focusing on specific compounds such as oxypeucedanin and prantschimgin.

“Electrochemical Properties of Fused Pyrimidine-Triazole Heterocyclic Molecules as Novel Drug Candidates”

  • Journal: Turkish Journal of Pharmaceutical Sciences
  • Year: 2024
  • DOI: 10.4274/TJPS.GALENOS.2023.46095
  • Details: This paper investigates the electrochemical properties of new heterocyclic compounds that could serve as drug candidates.

“Label-Free and Label-Based Electrochemical Detection of Disease Biomarker Proteins”

  • Journal: ADMET and DMPK
  • Year: 2024
  • DOI: 10.5599/ADMET.2162
  • Details: This research focuses on developing electrochemical methods for detecting disease biomarkers both with and without labels.

“Biosensor Integrated Brain-on-a-Chip Platforms: Progress and Prospects in Clinical Translation”

  • Journal: Biosensors and Bioelectronics
  • Year: 2023
  • DOI: 10.1016/J.BIOS.2023.115100
  • Details: This review highlights advancements in integrating biosensors with brain-on-a-chip technology, discussing potential clinical applications.

“Electrochemical Investigation of Hydroxyapatite-Lanthanum Strontium Cobalt Ferrite Composites (HA-LSCF) for SARS-CoV-2 Aptasensors”

  • Journal: RSC Advances
  • Year: 2023
  • Details: The paper explores the use of hydroxyapatite and lanthanum strontium cobalt ferrite composites in developing aptasensors for detecting SARS-CoV-2.

Research Timeline

Dr. Topkaya Cetinā€™s research timeline reflects a consistent focus on biosensing technologies and electrochemistry. Starting with her Ph.D. research on electrochemical DNA biosensors, her subsequent projects included tissue engineering and nanomaterials-based biosensing techniques during her postdoctoral research. Her timeline highlights key research milestones, including significant international collaborations and the development of novel biosensing methods.

Collaborations and Projects

Throughout her career, Dr. Topkaya Cetin has collaborated with leading researchers and institutions globally. Notable collaborations include her work with Ali Khademhosseini at Harvard-MIT, Michael Holzinger at Joseph Fourier University, and Frank Vollmer at the Max Planck Institute. These collaborations have advanced her research in tissue engineering, nanophotonics, and biosensing technologies, contributing to innovative projects and significant scientific advancements in her field.

Strengths of the Best Researcher Award

  1. Innovative Research Focus: Dr. Seda Nur Topkaya Cetin’s research in electrochemical biosensors and nanomaterials represents cutting-edge science. Her focus on developing novel biosensing technologies for medical diagnostics, including the detection of gene hypermethylation and single-point mutations, underscores her commitment to advancing molecular diagnostics.
  2. High Citation Impact: With 1,613 citations across 1,514 documents and an h-index of 18, Dr. Topkaya Cetin’s work is highly influential in her field. This citation record reflects the significant impact and recognition of her research contributions.
  3. Diverse Expertise and International Experience: Her extensive international research experience, including positions at Harvard Medical School, Max Planck Institute, and Joseph Fourier University, enhances her profile as a leading researcher. This diverse background contributes to her ability to integrate different scientific approaches and technologies.
  4. Prestigious Awards and Recognitions: Dr. Topkaya Cetin’s accolades, such as the Best Poster Competition Third Prize and the 65th Lindau Nobel Laureate Meeting participation, highlight her recognized excellence in research. These awards validate her contributions and expertise in the scientific community.
  5. Comprehensive Publications Record: Her extensive list of publications in reputable journals, such as ADMET and DMPK and Biosensors and Bioelectronics, demonstrates her active engagement in advancing the field. These publications cover a wide range of topics, from biosensor applications to electrochemical investigations, reflecting the breadth and depth of her research.

Areas for Improvement

  1. Increased Focus on Practical Applications: While Dr. Topkaya Cetinā€™s research is highly innovative, a greater emphasis on translating her findings into practical, real-world applications could enhance the societal impact of her work. Bridging the gap between research and commercial or clinical use could further extend the relevance of her studies.
  2. Expansion of Collaborative Networks: Although she has collaborated with prestigious institutions, expanding her network to include interdisciplinary collaborations, especially with researchers in fields like data science and machine learning, could provide new insights and applications for her biosensing technologies.
  3. Inclusion of More Diverse Research Areas: While her work is highly specialized in electrochemistry and biosensing, exploring additional related fields, such as bioinformatics or computational modeling, could offer new perspectives and enhance her research outcomes.
  4. Enhanced Focus on Emerging Technologies: Integrating emerging technologies, such as AI-driven biosensing or advanced nanomaterial innovations, could keep her research at the forefront of scientific advancement and address new challenges in molecular diagnostics.
  5. Increased Public Engagement and Outreach: Expanding efforts in science communication and public outreach could help in disseminating her research findings more widely. Engaging with broader audiences through popular science talks, media interactions, or educational initiatives could enhance public awareness and appreciation of her work.

Conclusion

Dr. Seda Nur Topkaya Cetinā€™s achievements and contributions to the fields of electrochemistry, biosensor development, and nanomaterials make her a deserving recipient of the Best Researcher Award. Her innovative research, significant citation impact, and extensive international experience underscore her status as a leading figure in her field. However, there are opportunities to further enhance the practical applications of her work, expand collaborative networks, and engage with emerging technologies and public outreach. Addressing these areas could amplify the impact of her research and contribute to even greater advancements in molecular diagnostics and biosensing technologies.

Yuhao Liu | Molecular Biology | Best Paper Award

Dr. Yuhao Liu | Molecular Biology | Best Paper Award

Doctorate at The First Affiliated Hospital, Guangzhou University of Chinese Medicine, China

Dr. Yuhao Liu is a distinguished surgeon and researcher at The First Affiliated Hospital, Guangzhou University of Chinese Medicine. Holding both a Doctor of Medicine degree and a joint Ph.D. from the University of Western Australia, Dr. Liu has established a prominent career in orthopedics. He is known for his significant contributions to the field through extensive research, numerous publications, and innovations in orthopedic medicine. His role as Surgeon-in-charge underscores his leadership and expertise in both clinical and research settings.

Author Metrics

Scopus Profile

ORCID Profile

Dr. Liu has a notable academic footprint with 15 SCI papers and 6 Chinese papers as the first or corresponding author. He has been recognized with the ICOBR 2018 “Best Paper Award” for his outstanding contributions. His research impact is reflected in his high citation index, indicative of the relevance and influence of his work within the scientific community.

  • Citations: 480 citations across 442 documents
  • Number of Documents: 30
  • h-index: 10

Education

Dr. Liu completed his Doctor of Medicine degree and pursued a joint Ph.D. from the University of Western Australia. His academic journey was further enriched by his role as a visiting scholar under a national government scholarship, which broadened his research perspective and international experience.

Research Focus

Dr. Liuā€™s research primarily centers on orthopedics, particularly exploring the pathological mechanisms of conditions such as femoral head necrosis. His work involves investigating oxidative stress and screening traditional Chinese medicine monomers for potential treatments in orthopedic diseases.

Professional Journey

Dr. Liu has had a dynamic career trajectory marked by leadership and research excellence. As a young scientific talent in Guangzhou, he has led numerous research projects funded by prestigious organizations such as the National Natural Science Foundation of China. His professional journey includes significant roles in academic and clinical settings, underpinned by his active participation in international orthopedic conferences.

Honors & Awards

Dr. Liu has received several prestigious awards, including the “Outstanding Doctoral Dissertation” and “Star of the Year” awards from his university. Additionally, his exceptional research work has been recognized internationally with the ICOBR 2018 “Best Paper Award,” highlighting his contributions to the field of orthopedics.

Publications Noted & Contributions

Dr. Liu has published extensively in high-impact journals, with 15 SCI papers and 6 Chinese papers to his name. His research has led to the discovery of the oxidative stress mechanism in femoral head necrosis and the screening of traditional Chinese medicine for orthopedic applications. His contributions are also evidenced by two authorized national invention patents.

“The Preserved Thickness Ratio of the Femoral Head Contributes to the Collapse Predictor of Osteonecrosis”

  • Journal: Orthopaedic Surgery
  • Publication Date: 2024
  • DOI: 10.1111/OS.13967
  • Contributors: Zhang, Jiahao; Zhou, Chi; Fan, Yinuo; Fang, Hanjun; Li, Weifeng; Wang, Xiyi; Chen, Zhenqiu; Liu, Yuhao
  • Summary: This study explores how the preserved thickness ratio of the femoral head can predict collapse in osteonecrosis cases.

“Dihydrotanshinone I Attenuates Estrogen-Deficiency Bone Loss through RANKL-Stimulated NF-ĪŗB, ERK and NFATc1 Signaling Pathways”

  • Journal: International Immunopharmacology
  • Publication Date: October 2023
  • DOI: 10.1016/j.intimp.2023.110572
  • Contributors: Chao Ma; Liang Mo; Zhangzheng Wang; Deqiang Peng; Chi Zhou; Wei Niu; Yuhao Liu; Zhenqiu Chen
  • Summary: This research investigates how Dihydrotanshinone I can mitigate bone loss associated with estrogen deficiency via specific signaling pathways.

“Dragon Blood Resin Ameliorates Steroid-Induced Osteonecrosis of Femoral Head Through Osteoclastic Pathways”

  • Journal: Frontiers in Cell and Developmental Biology
  • Publication Date: August 22, 2023
  • DOI: 10.3389/fcell.2023.1202888
  • Contributors: Yuhao Liu; Liang Mo; Hongduo Lu; Yangwenxiang Wei; Jiahao Zhang; Samuel Bennett; Jiake Xu; Chi Zhou; Bin Fang; Zhenqiu Chen
  • Summary: This paper focuses on how Dragon Blood Resin can counteract steroid-induced osteonecrosis through effects on osteoclastic pathways.

“Loureirin B Downregulates Osteoclast Differentiation of Bone Marrow Macrophages by Targeting the MAPK Signaling Pathway”

  • Journal: Scientific Reports
  • Publication Date: August 23, 2022
  • DOI: 10.1038/s41598-022-18287-5
  • Contributors: Jiahao Zhang; Liang Mo; Haoran Huang; Jiake Xu; Yinuo Fan; Weifeng Li; Haibin Wang; Chi Zhou; Hanjun Fang; Wei He et al.
  • Summary: The study evaluates how Loureirin B affects osteoclast differentiation through the MAPK signaling pathway.

“Integrated Analysis of Crucial Genes and miRNAs Associated with Osteoporotic Fracture of Type 2 Diabetes”

  • Journal: BioMed Research International
  • Publication Date: August 10, 2022
  • DOI: 10.1155/2022/3921570
  • Contributors: Liang Mo; Zhangzheng Wang; Haoran Huang; Jianxiong Li; Chao Ma; Jiahao Zhang; Fayi Huang; Wei He; Yuhao Liu; Chi Zhou et al.
  • Summary: This article presents an integrated analysis of genes and miRNAs related to osteoporotic fractures in the context of Type 2 Diabetes.

Research Timeline

Dr. Liuā€™s research activities include the completion of 11 projects and involvement in consultancy and industry projects. His ongoing research continues to advance the understanding and treatment of orthopedic conditions, reflecting a consistent and impactful research trajectory.

Strengths of Dr. Yuhao Liu’s “Best Paper Award” Research

Innovative Contributions: Dr. Liuā€™s award-winning research, particularly in areas like oxidative stress mechanisms in femoral head necrosis and traditional Chinese medicine applications, showcases innovation and originality in the field of orthopedics. His focus on novel treatment pathways, such as those involving Dragon Blood Resin and Dihydrotanshinone I, demonstrates a forward-thinking approach to addressing complex orthopedic conditions.

High Citation Impact: The citation metrics of Dr. Liuā€™s work indicate substantial recognition and influence within the scientific community. With 480 citations across 442 documents, his research has clearly resonated with and impacted other scholars and practitioners in his field.

Interdisciplinary Approach: Dr. Liuā€™s research integrates traditional Chinese medicine with modern orthopedic practices, reflecting a multidisciplinary approach that can lead to more holistic and effective treatment strategies. This integration is valuable for broadening the scope and impact of his research.

Publication in High-Impact Journals: Dr. Liuā€™s work is published in reputable, high-impact journals such as Orthopaedic Surgery and International Immunopharmacology. These journals are known for their rigorous peer-review processes and wide readership, which further amplifies the visibility and influence of his research.

Recognition and Awards: The ICOBR 2018 “Best Paper Award” is a testament to the quality and relevance of Dr. Liuā€™s research. Such accolades not only enhance his professional reputation but also underscore the significance of his contributions to the field of orthopedics.

Areas for Improvement

Expanding Collaborative Networks: While Dr. Liuā€™s research is impactful, further expanding his collaborative networks, particularly with international researchers and institutions, could enhance the scope and applicability of his findings. Greater collaboration could lead to more diverse research perspectives and opportunities.

Increasing h-index: Dr. Liuā€™s h-index of 10, while respectable, indicates room for growth in terms of the number of highly cited papers. Continued focus on high-impact, widely cited research could enhance this metric, reflecting even greater influence within the academic community.

Diversifying Research Topics: While Dr. Liuā€™s focus on oxidative stress and traditional Chinese medicine is strong, exploring additional orthopedic topics or emerging trends in the field could further broaden his research impact and relevance.

Enhancing Public Engagement: Increasing efforts to communicate research findings to a broader audience, including through public talks, media appearances, or lay summaries, could help bridge the gap between academic research and public understanding. This could also enhance the practical impact of his work.

Improving Publication Frequency: While Dr. Liu has a substantial number of publications, increasing the frequency of high-quality publications could further strengthen his academic profile and contribute to ongoing advancements in orthopedic research.

Conclusion

Dr. Yuhao Liu’s research has made significant strides in the field of orthopedics, particularly through innovative approaches and the integration of traditional Chinese medicine. His recognition with the ICOBR 2018 “Best Paper Award” and high citation metrics reflect the impact and relevance of his work. To further enhance his research trajectory, Dr. Liu might consider expanding collaborative networks, diversifying research topics, and increasing public engagement. By addressing these areas, he can continue to build on his successes and drive further advancements in orthopedic medicine.

Hesham Alsoghier | Chemistry | Best Researcher Award

Dr. Hesham Alsoghier | Chemistry | Best Researcher Award-

Doctorate at South Valley University Egypt, Chemistry

Hesham Mohammed Alsoghier is a dedicated chemist specializing in bio-organic and bio-inorganic chemistry with a focus on the synthesis and characterization of metal coordination compounds and organic ligands. With a robust educational background from South Valley University and international research experience, Hesham’s expertise spans spectrophotometric, computational, and analytical chemistry. His current research aims to explore innovative approaches for Alzheimer’s disease treatment through novel bifunctional compounds.

Author Metrics

Scopus Profile

ORCID Profile

Hesham’s research contributions are reflected in several high-impact publications. His work, published in reputable journals, includes studies on the spectral behavior of azo compounds, potential anti-Alzheimer’s agents, and the structural features of chemical tautomers. Metrics such as citations, h-index, and journal impact factors underscore his influence and recognition in the field.

  • Citations: 104 citations across 91 documents
  • Documents: 12 publications
  • h-index: 5

Education

Hesham completed his B.Sc. in Chemistry with honors from South Valley University, followed by a Masterā€™s degree in Inorganic and Computational Chemistry from the same institution. His academic journey continued with a Ph.D. from South Valley University, focusing on the spectral behavior of azo benzothiazole derivatives. Additionally, he pursued advanced studies in Bio-Inorganic Chemistry at Instituto Superior TĆ©cnico, Universidade de Lisboa, and participated in an international masterā€™s program at Adam Mickiewicz University.

Research Focus

Hesham’s research primarily revolves around the synthesis and characterization of bio-organic and bio-inorganic compounds, particularly their applications in disease treatment and metal coordination chemistry. His work includes spectral investigations, computational studies, and bioactivity assessments of novel chemical compounds. His current research is dedicated to developing bifunctional compounds with potential therapeutic benefits for Alzheimer’s disease.

Professional Journey

Beginning as a Teaching Assistant at South Valley University, Hesham’s career has progressed to his current role as a Lecturer Assistant, where he continues to contribute to both teaching and research. His professional journey includes significant research stints in Portugal and Poland, where he expanded his expertise in bio-inorganic chemistry and photochemistry. His role involves not only academic responsibilities but also active participation in research projects and collaborations.

Honors & Awards

Hesham has received several accolades for his academic and research achievements. Notable honors include recognition for his exceptional contributions to research in bio-inorganic chemistry and his successful completion of advanced international programs. These awards reflect his commitment to excellence in both teaching and research.

Publications Noted & Contributions

Heshamā€™s publication record includes several influential papers in high-impact journals. Key contributions include studies on the optical properties of azo dyes, the development of anti-Alzheimer’s agents, and investigations into chemical tautomerism. His work has been presented at international conferences and has significantly contributed to advancements in his field.

“Green electro-organic synthesis of a novel catechol derivative based on o-benzoquinone nucleophilic addition”

  • Journal: New Journal of Chemistry
  • Year: 2023
  • DOI: 10.1039/D2NJ04530C
  • Contributors: Mohamed Abd-Elsabour, Hytham F. Assaf, Ahmed M. Abo-Bakr, Abdulrahman G. Alhamzani, Mortaga M. Abou-Krisha, Aamal A. Al-Mutairi, Hesham M. Alsoghier

“A novel organic semiconductor 4-phenylthiazol-2-yl-(phenylhydrazono) acetonitrile (PTPA) thin films: synthesis, optical and electrical properties”

  • Journal: Scientific Reports
  • Date: August 10, 2023
  • DOI: 10.1038/s41598-023-39027-3
  • Contributors: Amr Attia Abuelwafa, Sahar Elnobi, M. AmĆ©lia Santos, Hesham M. Alsoghier

“Molecular docking, modeling, semiempirical calculations studies and in vitro evaluation of new synthesized pyrimidin-imide derivatives”

  • Journal: Journal of Molecular Structure
  • Year: 2022
  • DOI: 10.1016/j.molstruc.2021.131548
  • EID: 2-s2.0-85115989286
  • Contributors: Abo-Bakr, A.M., Alsoghier, H.M., Abdelmonsef, A.H.

“A Novel Electrochemical Sensor for Detection of Nicotine in Tobacco Products Based on Graphene Oxide Nanosheets Conjugated with (1,2-Naphthoquinone-4-Sulphonic Acid) Modified Glassy Carbon Electrode”

  • Journal: Nanomaterials
  • Date: July 9, 2022
  • DOI: 10.3390/nano12142354
  • Contributors: M. Abd-Elsabour, Hesham M. Alsoghier, Abdulrahman G. Alhamzani, Mortaga M. Abou-Krisha, Tarek A. Yousef, Hytham F. Assaf

“A novel alternative methods for decalcification of water resources using green agro-ashes”

  • Journal: Molecules
  • Year: 2021
  • DOI: 10.3390/molecules26226777
  • Contributors: El-Nahas, S., Arafat, A.S., Din, H.S.E., Alhamzani, A.G., Abou-Krisha, M.M., Alsoghier, H.M.

Research Timeline

From 2008 to 2012, Hesham conducted research for his Masterā€™s thesis, focusing on the spectral investigations of azo compounds. This foundational work laid the groundwork for his subsequent studies. Between 2012 and 2013, he expanded his expertise through advanced studies in photochemistry at Adam Mickiewicz University, where he deepened his understanding of surface electro radiation and photo-chemistry. During 2014 to 2015, Hesham engaged in significant research at Instituto Superior TĆ©cnico, where he worked on the synthesis and characterization of bifunctional compounds aimed at Alzheimer’s disease treatment. Following this, from 2015 to 2018, he completed his Ph.D. research at South Valley University, investigating the spectral behavior of azo benzothiazole derivatives. Since 2018, he has continued his research at South Valley University, focusing on bio-organic and bio-inorganic chemistry, advancing his work on novel chemical compounds with potential therapeutic applications.

Collaborations and Projects

Hesham has collaborated with leading researchers and institutions, including partnerships with Instituto Superior TĆ©cnico, Universidade de Lisboa, and Adam Mickiewicz University. His collaborative projects focus on the development of novel chemical compounds and their applications in medicine. He has also participated in various research initiatives and workshops, contributing to advancements in his field through collaborative efforts.

Strengths of the Best Researcher Award for Dr. Hesham Alsoghier:

Innovative Research Focus: Dr. Hesham Alsoghier’s research on bifunctional compounds for Alzheimer’s disease treatment is highly innovative and relevant. His focus on addressing significant medical challenges showcases a commitment to impactful scientific work.

High-Impact Publications: The inclusion of his research in reputable journals such as Scientific Reports and New Journal of Chemistry demonstrates the high quality and relevance of his work. His publications cover a range of cutting-edge topics, from organic semiconductors to electrochemical sensors.

International Collaboration: Dr. Alsoghier’s experience working with institutions like Instituto Superior TĆ©cnico and Adam Mickiewicz University highlights his ability to collaborate effectively with leading researchers worldwide. This enhances the global impact of his work.

Diverse Expertise: His background in bio-organic and bio-inorganic chemistry, along with expertise in computational and analytical techniques, provides a strong foundation for tackling complex research problems. This multidisciplinary approach enriches his research contributions.

Recognition and Awards: The receipt of the Best Researcher Award and other honors underscores Dr. Alsoghier’s excellence in research and his contributions to advancing knowledge in his field. These accolades reflect his dedication and impact.

Areas for Improvement:

Citations and h-Index: While Dr. Alsoghier has made significant contributions, his citation count and h-index indicate room for growth. Increasing visibility and impact through strategic collaborations and higher-profile publications could enhance these metrics.

Publication Quantity: With 12 publications, Dr. Alsoghier’s output is notable but could be expanded. Publishing more frequently in high-impact journals could further establish his research presence and influence.

Research Scope Diversification: While his focus on Alzheimer’s disease is promising, exploring additional areas or applications within bio-organic and bio-inorganic chemistry could broaden the scope and impact of his research.

Grant Acquisition: Strengthening efforts in securing research grants and funding could support more extensive and ambitious projects. This could involve applying for larger grants or participating in collaborative grant proposals.

Public Engagement and Outreach: Increasing involvement in public outreach activities and science communication could enhance the visibility of his research and its societal relevance. Engaging with broader audiences through seminars, public talks, or media could also raise awareness of his work.

Conclusion:

Dr. Hesham Alsoghier is a distinguished chemist whose innovative research and high-impact publications underscore his significant contributions to bio-organic and bio-inorganic chemistry. His international collaborations and recognition through awards highlight his commitment and excellence in the field. To further enhance his impact, focusing on increasing citation metrics, expanding publication output, diversifying research scope, securing additional funding, and engaging with the public could be beneficial. Overall, Dr. Alsoghierā€™s achievements and ongoing research efforts demonstrate his potential to continue making substantial advancements in chemistry and related fields.

Eslam Syala | Environment | Environmental Chemistry Award

Dr. Eslam Syala | Environment | Environmental Chemistry Award

Doctorate at Institute of Graduate Studies and Researches (IGSR), Alexandria University, 163 Horreya Avenue, Shatby, 21526, Alexandria, Egypt.

Eslam Abdel Aziz Hussien Syala is a dedicated researcher and processing engineer specializing in Material Science. He holds a Ph.D. from Alexandria University and has a robust background in both practical engineering and academic research. His career is characterized by a strong commitment to advancing scientific knowledge, demonstrated through his extensive research publications, peer reviewing activities, and teaching roles. Syala’s diverse professional experiences, including technical translation and engineering roles, underscore his multifaceted expertise and contribution to the field.

Author Metrics

Scopus Profile

ORCID Profile

Google Scholar Profile

Eslam Syala has a significant record of publications in high-impact journals, reflecting his active role in the scientific community. His research has been featured in esteemed journals such as Scientific Reports, Ceramics International, and the Journal of Composite Materials. Syalaā€™s work on various topics within Material Science, including composites and waste management, highlights his impactful contributions to the field. His role as a peer reviewer for numerous journals further underscores his engagement and influence in the academic community.

Citations and Documents: Eslam Syala has accrued a total of 193 citations across 157 documents. This indicates that his research work is frequently referenced by other scholars, reflecting its impact and relevance in the field of Material Science.

Documents: He has published 11 documents, which include research papers, articles, and possibly conference papers or reports. The number of documents gives an idea of the volume of his scholarly contributions.

h-index: Syala has an h-index of 7. This metric suggests that he has at least 7 papers that have each been cited at least 7 times. The h-index is used to measure both the productivity and citation impact of a researcherā€™s publications.

Education

Eslam Syalaā€™s educational background is distinguished by his advanced degrees in Material Science and Metallurgy Engineering. He earned his Ph.D. in Material Science from Alexandria University with a high CGPA of 3.722/4, following a Masterā€™s degree in the same field, where he ranked in the top 5% of his class. His undergraduate studies in Metallurgy Engineering at AL-Azhar University were marked by a strong academic performance, culminating in a highly praised graduation project on titanium extraction.

Research Focus

Syalaā€™s research focus spans several key areas within Material Science. His work includes the development and characterization of composite materials, the study of waste management solutions such as using cement kiln dust for wastewater treatment, and the analysis of glass systems’ thermal and kinetic properties. These research areas reflect his commitment to addressing practical challenges and advancing scientific understanding in materials technology.

Professional Journey

Eslam Syalaā€™s professional journey combines roles in engineering, academia, and technical translation. He currently serves as a Processing Engineer at the Egyptian Black Sand Company, where he manages operations and oversees plant commissioning. In addition to his engineering role, Syala is a part-time lecturer, teaching courses related to welding, corrosion control, and materials science. His experience as a technical translator for major industrial projects adds to his diverse skill set and professional expertise.

Honors & Awards

In September 2010, Eslam Syala received an award for academic distinction from the Faculty of Engineering at AL-Azhar University. This honor recognized his exceptional academic performance during his undergraduate studies, highlighting his dedication and excellence in his field of study.

Publications Noted & Contributions

Eslam Syala has authored and co-authored numerous influential publications in respected journals, addressing various aspects of Material Science. His notable contributions include studies on the treatment of dye-containing wastewater, thermal protection of steel, and the characterization of polymer composites. These publications demonstrate his extensive research efforts and impact in advancing material science knowledge.

“Thermal protection of steel using various ceramic-like fireproofing coatings systems: Comparative study”

  • Journal: Ceramics International
  • Publication Date: October 2024
  • DOI: 10.1016/j.ceramint.2024.06.123
  • Contributors: Essam El-Rafey, Mohamed Kamal Mostafa, Mohamed Abdel Gawad Konsouh, Mohamed M. Yousry, Eslam Syala
  • Summary: This study provides a comparative analysis of various ceramic-like fireproofing coatings designed to enhance the thermal protection of steel. The research evaluates the performance and effectiveness of different coating systems, aiming to identify the most efficient solutions for fire protection in industrial applications.

“The effective treatment of dye-containing simulated wastewater by using the cement kiln dust as an industrial waste adsorbent”

  • Journal: Scientific Reports
  • Publication Date: June 25, 2024
  • DOI: 10.1038/s41598-024-64191-5
  • Contributors: Eslam Syala, Wagih A. Sadik, Abdel-Ghaffar M. El-Demerdash, Waffa Mekhamer, M. Essam El-Rafey
  • Summary: This article investigates the use of cement kiln dust as an adsorbent for treating dye-containing simulated wastewater. The study demonstrates the effectiveness of using industrial waste materials for environmental remediation, providing a sustainable solution for wastewater treatment.

“Characterization of the extruded polypropylene filled with cement kiln dust composite”

  • Journal: Journal of Composite Materials
  • Publication Date: March 2023
  • DOI: 10.1177/00219983221147387
  • Contributors: Essam El-Rafey, Wagih A Sadik, Tawfik A Ramadan, Shimaa El-Farouk, Eslam Syala
  • Summary: This research focuses on the characterization of a composite material made from extruded polypropylene and cement kiln dust. The study examines the physical and mechanical properties of the composite, highlighting its potential applications and benefits in various industries.

“A study on the physical, mechanical, thermal properties and soil biodegradation of HDPE blended with PBS/HDPE-g-MA”

  • Journal: Polymer Bulletin
  • Publication Date: April 2022
  • DOI: 10.1007/s00289-021-03623-y
  • Contributors: E. El-Rafey, Walaa M. Walid, Eslam Syala, Abbas Anwar Ezzat, Salah F. Abdellah Ali
  • Summary: This study explores the physical, mechanical, and thermal properties of High-Density Polyethylene (HDPE) blended with Poly(butylene succinate) (PBS) and HDPE-g-MA. It also assesses the biodegradation of the material in soil, offering insights into its environmental impact and potential for sustainable use.

“Natural Fiber Reinforced Unsaturated Polyester Resin Filled with Bio-based Calcium Carbonate: Preparation and Examination”

  • Journal: Fibers and Polymers
  • Publication Date: April 11, 2022
  • DOI: 10.1007/s12221-022-4460-1
  • Part of ISSN: 1229-9197, 1875-0052
  • Summary: This paper discusses the development of a natural fiber reinforced unsaturated polyester resin incorporated with bio-based calcium carbonate. The research focuses on the preparation, examination, and properties of the composite material, emphasizing its potential applications and environmental benefits.

Research Timeline

Syalaā€™s research timeline reflects a progression from fundamental studies in glass systems and their properties to practical applications in materials technology. From 2017 to 2020, he focused on kinetic characterization and thermal properties of tellurite glasses. In recent years, his research has shifted towards practical applications, including composite materials and waste management solutions, showcasing his evolving research interests and contributions.

Strengths of the Environmental Chemistry Award for Dr. Eslam Syala:

Interdisciplinary Impact: Dr. Syala’s research spans a diverse range of topics within Material Science, including waste management, composite materials, and thermal protection. This breadth demonstrates his ability to address various environmental challenges through innovative approaches, aligning well with the interdisciplinary nature of environmental chemistry.

High-Impact Publications: His work is published in reputable journals like Scientific Reports, Ceramics International, and Journal of Composite Materials. These journals are known for their rigorous peer-review processes and high visibility, indicating the significant impact and relevance of his research.

Practical Applications: Dr. Syalaā€™s focus on practical applications, such as using industrial waste for wastewater treatment and developing fireproofing coatings, highlights his commitment to solving real-world environmental issues. This practical approach is highly valued in the field of environmental chemistry.

Commitment to Sustainability: His research on sustainable materials and waste management, such as the use of cement kiln dust and the development of biodegradable composites, reflects a strong commitment to environmental sustainability. This aligns with the goals of environmental chemistry to promote eco-friendly solutions.

Academic and Professional Experience: Dr. Syalaā€™s extensive experience in both academia and industry enhances his ability to contribute to environmental chemistry. His roles as a processing engineer, lecturer, and peer reviewer demonstrate a well-rounded expertise that supports his research activities.

Areas for Improvement:

Increased Citation Impact: With an h-index of 7 and a total of 193 citations across 157 documents, there is potential for Dr. Syala to increase the visibility and citation impact of his work. Strategies could include targeting high-impact journals, engaging in collaborative research, and enhancing the dissemination of his findings.

Broader Research Topics: While Dr. Syala’s work is impressive, expanding his research to include emerging topics in environmental chemistry, such as climate change mitigation or advanced green technologies, could further strengthen his profile in this field.

Enhanced Outreach and Communication: Increasing outreach efforts, such as public lectures, workshops, or media engagement, could help raise awareness of his research and its implications for environmental chemistry. Effective science communication can amplify the impact of his findings.

Interdisciplinary Collaborations: Strengthening collaborations with researchers from related fields, such as environmental engineering or environmental policy, could provide new insights and broaden the scope of his research. This interdisciplinary approach can lead to more comprehensive solutions to environmental challenges.

Grant Funding and Research Opportunities: Pursuing additional research funding and exploring new research opportunities could enhance his ability to undertake larger-scale studies and contribute further to the field of environmental chemistry. Securing grants for innovative projects can also increase his research impact.

Conclusion:

Dr. Eslam Syalaā€™s work in material science, particularly in areas related to environmental chemistry, demonstrates a strong commitment to addressing practical environmental challenges through innovative solutions. His impressive publication record, practical applications of his research, and diverse professional experience highlight his contributions to the field. By focusing on increasing the impact of his work, exploring new research topics, enhancing outreach efforts, fostering interdisciplinary collaborations, and securing additional funding, Dr. Syala can further strengthen his position as a leading researcher in environmental chemistry. His ongoing efforts and achievements position him well for continued success and recognition in this important field.

Athanassios Philippopoulos | Inorganic Chemistry | Best Researcher Award

Assoc Prof Dr. Athanassios Philippopoulos | Inorganic Chemistry | Best Researcher Award

Associate Professor at National and Kapodistrian University of Athens/Chemistry Department, Greece

Athanassios Philippopoulos is an Associate Professor in the Laboratory of Inorganic Chemistry at the National and Kapodistrian University of Athens. His research spans organometallic and coordination chemistry, with a focus on applying nanotechnologies to energy and environmental challenges. Philippopoulos has made significant contributions to renewable energy technologies, particularly dye-sensitized solar cells, and bio-inorganic chemistry, including metal-based drugs. His academic career is marked by substantial publications and active involvement in advancing both fundamental and applied chemistry.

Author Metrics

Scopus Profile

ORCID Profile

Philippopoulos has an extensive scholarly impact, with over 1300 citations according to Web of Science (H-index 18) and more than 1520 citations on Google Scholar (H-index 19). His work reflects a strong presence in the fields of organometallic and coordination chemistry, with significant influence on both theoretical and practical aspects of these disciplines.

Education

Philippopoulos obtained his Bachelor of Science in Chemistry from the University of Ioannina in 1992. He continued his studies at the same institution, completing his Ph.D. in Inorganic-Organometallic Chemistry in 1997. His advanced education provided a robust foundation for his subsequent research and academic career.

Research Focus

Philippopoulosā€™s research encompasses several key areas: organometallic and coordination chemistry, nanotechnologies for energy and environmental applications, and bio-inorganic chemistry. His work in renewable energy resources includes the development of dye-sensitized solar cells. Additionally, he explores metal-based drugs and their applications in medicine, alongside catalysis and general inorganic chemistry.

Professional Journey

Philippopoulos began his professional career with postdoctoral research at the University of Ioannina and Humboldt University of Berlin. He then served as a Research Associate at the Institute of Physical Chemistry, NCSR “Demokritos,” before joining the National and Kapodistrian University of Athens as an Associate Professor in 2021. His career trajectory reflects a blend of rigorous research and impactful academic roles.

Honors & Awards

Throughout his career, Philippopoulos has received several prestigious awards and fellowships, including those from the Institute of Physical Chemistry, the IKYDA Fellowship, and various scholarships from the French Government and Erasmus Program. These accolades highlight his exceptional contributions to the field of chemistry and his commitment to advancing scientific knowledge.

Publications Noted & Contributions

Philippopoulos has authored over 50 peer-reviewed journal articles and delivered more than 65 conference presentations. His work includes one invited book chapter and numerous contributions to academic journals as an editor and reviewer. His publications are noted for their impact on organometallic chemistry, nanotechnology, and renewable energy research.

Ruthenium <i>p</i>-Cymene Complexes Incorporating Substituted Pyridineā€“Quinoline-Based Ligands: Synthesis, Characterization, and Cytotoxic Properties

Publication Details:
Journal: Molecules
Date: July 2024
DOI: 10.3390/molecules29133215
Role: Author
Contributors: Afroditi Kokkosi, Elpida Garofallidou, Nikolaos Zacharopoulos, Nikolaos Tsoureas, Konstantina Diamanti, Nikolaos S. Thomaidis, Antigoni Cheilari, Christina Machalia, Evangelia Emmanouilidou, Athanassios Philippopoulos

This article explores the synthesis and characterization of ruthenium <i>p</i>-cymene complexes with substituted pyridine-quinoline ligands. It examines their potential cytotoxic properties, contributing to the field of metal-based anticancer agents.

Anti-Inflammatory and Antithrombotic Potential of Metal-Based Complexes and Porphyrins

Publication Details:
Journal: Compounds
Date: June 2024
DOI: 10.3390/compounds4020023
Role: Author
Contributors: Alexandros Tsoupras, Sofia Pafli, Charilaos Stylianoudakis, Kalliopi Ladomenou, C.A. Demopoulos, Athanassios Philippopoulos

This study evaluates the anti-inflammatory and antithrombotic activities of various metal-based complexes and porphyrins. The findings offer insights into their therapeutic potential for cardiovascular and inflammatory diseases.

First-Row Transition Metal Complexes Incorporating the 2-(2ā€²-pyridyl)quinoxaline Ligand (pqx), as Potent Inflammatory Mediators: Cytotoxic Properties and Biological Activities against the Platelet-Activating Factor (PAF) and Thrombin

Publication Details:
Journal: Molecules
Date: October 2023
DOI: 10.3390/molecules28196899
Role: Author
Contributors: Antigoni Margariti, Vasiliki D. Papakonstantinou, George Stamatakis, C.A. Demopoulos, Christina Machalia, Evangelia Emmanouilidou, Gregor Schnakenburg, Maria-Christina Nika, Nikolaos S. Thomaidis, Athanassios Philippopoulos

The paper focuses on the cytotoxic effects and biological activities of first-row transition metal complexes with 2-(2ā€²-pyridyl)quinoxaline ligands. It investigates their role as inflammatory mediators and their impact on platelet-activating factors and thrombin.

Tin(II) and Tin(IV) Complexes Incorporating the Oxygen Tripodal Ligands [(<i>Ī·</i><sup>5</sup>-C<sub>5</sub>R<sub>5</sub>)Co{P(OEt)<sub>2</sub>O}<sub>3</sub>]<sup>āˆ’</sup>, (R = H, Me; Et = -C<sub>2</sub>H<sub>5</sub>) as Potent Inflammatory Mediator Inhibitors: Cytotoxic Properties and Biological Activities against the Platelet-Activating Factor (PAF) and Thrombin

Publication Details:
Journal: Molecules
Date: February 2023
DOI: 10.3390/molecules28041859
Role: Author
Contributors: Alexandros Kalampalidis, Artemis Damati, Demetrios Matthopoulos, Alexandros Tsoupras, C.A. Demopoulos, Gregor Schnakenburg, Athanassios Philippopoulos

This article investigates the cytotoxic properties and biological activities of tin(II) and tin(IV) complexes with oxygen tripodal ligands. It highlights their effectiveness as inhibitors of inflammatory mediators like PAF and thrombin.

Sterically Demanding Pyridine-Quinoline Anchoring Ligands as Building Blocks for Copper(<scp>i</scp>)-Based Dye-Sensitized Solar Cell (DSSC) Complexes

Publication Details:
Journal: Dalton Transactions
Date: 2022
DOI: 10.1039/d2dt02382b
Role: Author
Contributors: Anastasios Peppas, Demetrios Sokalis, Dorothea Perganti, Gregor Schnakenburg, Polycarpos Falaras, Athanassios Philippopoulos

This publication discusses the use of sterically demanding pyridine-quinoline ligands in designing copper(I)-based dye-sensitized solar cells. It contributes to the development of advanced materials for solar energy applications.

Research Timeline

Philippopoulos’s research career includes significant milestones, such as his postdoctoral studies from 1998 to 2003, his role as a Research Associate from 2003 to 2006, and his tenure as an Associate Professor since 2021. His research grants and projects reflect ongoing advancements in solar cell technology, chelation methods, and innovative materials.

Collaborations and Projects

Philippopoulos has been involved in various collaborative research projects, including those funded by the Hellenic Foundation for Research and Innovation and the General Secretariat for Research and Technology. His work has spanned areas like nanocrystalline solar cells and innovative cleaning methods for museum artifacts, showcasing his collaborative efforts in advancing chemistry and technology.

Strengths of the Best Researcher Award for Athanassios Philippopoulos

  1. Significant Scholarly Impact: Philippopoulos has made notable contributions to the fields of organometallic and coordination chemistry, with over 1300 citations on Web of Science and 1520 on Google Scholar. This indicates a strong influence and recognition of his work within the scientific community.
  2. Diverse Research Areas: His research spans several crucial areas, including renewable energy (dye-sensitized solar cells), bio-inorganic chemistry (metal-based drugs), and nanotechnologies. This broad focus demonstrates his versatility and impact across multiple subfields of chemistry.
  3. High-Quality Publications: Philippopoulos has published over 50 peer-reviewed journal articles and contributed to significant research outputs, such as studies on ruthenium complexes, metal-based drugs, and copper(I)-based dye-sensitized solar cells. This reflects his commitment to advancing scientific knowledge and addressing pressing challenges.
  4. Awards and Recognition: The recognition Philippopoulos has received, including the Best Researcher Award, highlights his exceptional contributions and the esteem in which he is held by the academic and research communities. His past honors from various prestigious institutions further validate his achievements.
  5. Active Academic Engagement: Philippopoulosā€™s role in numerous conference presentations and his involvement as an editor and reviewer for academic journals show his active engagement in the scientific community. This participation underscores his dedication to both research and the dissemination of knowledge.

Areas for Improvement

  1. Broader Research Collaborations: While Philippopoulos has been involved in several collaborative projects, expanding his network to include more international and interdisciplinary collaborations could enhance the scope and impact of his research.
  2. Interdisciplinary Integration: There is an opportunity to further integrate his research with other scientific disciplines, such as materials science or environmental engineering, to address complex challenges from multiple perspectives.
  3. Increased Public Outreach: Enhancing efforts to communicate his research findings to the general public and stakeholders outside the academic community could increase the societal impact and relevance of his work.
  4. Funding and Grants: While Philippopoulos has been involved in research funded by various grants, seeking additional funding opportunities or leading larger-scale, multi-institutional projects could provide more resources for ambitious research goals.
  5. Educational Contributions: Developing and incorporating innovative teaching methods or educational programs related to his research areas could further benefit students and early-career researchers, enriching the academic environment at his institution.

Conclusion

Athanassios Philippopoulos has made substantial contributions to inorganic chemistry, particularly in the areas of organometallic chemistry, renewable energy, and bio-inorganic chemistry. His extensive publication record, significant citations, and numerous awards reflect his outstanding research accomplishments and impact on the field. While there are areas for potential improvement, such as broadening collaborations and enhancing public outreach, his achievements and ongoing contributions position him as a leading figure in his field. The Best Researcher Award is a testament to his dedication and excellence in advancing scientific knowledge and addressing global challenges through chemistry.

Amelia Sweet | Computational Surface Science | Best Researcher Award

Ms. Amelia Sweet | Computational Surface Science | Best Researcher Award

Amelia Sweet at University of Iowa, United States

Amelia Sweet is a dedicated graduate student currently pursuing a Ph.D. in Computational Chemistry at the University of Iowa. Her academic and professional journey reflects a deep commitment to understanding and applying computational techniques in chemistry. Ameliaā€™s research focuses on the use of Density Functional Theory (DFT) to study molecular interactions, and she has a background in teaching and developing advanced materials for high-energy applications.

Author Metrics

Google Scholar Profile

Amelia has authored several significant publications in the field of computational chemistry. Her work, particularly the study of nitrobenzene adsorption on Ag(111) surfaces, has been recognized in peer-reviewed journals and presented at major conferences. The metrics reflecting the impact of her work, such as citation counts and journal impact factors, highlight her contributions to the field.

Education

Amelia Sweet is currently working towards a Ph.D. in Chemistry at the University of Iowa, where she is co-advised by Dr. Sara Mason and Dr. Scott Shaw. She holds a B.A. in Chemistry from Saint Maryā€™s University of Minnesota, where her thesis focused on a computational and spectroscopic study of tungsten-based polyoxometalates. Her educational background has provided a strong foundation in both theoretical and practical aspects of chemistry.

Research Focus

Ameliaā€™s research focuses on computational chemistry, particularly using Density Functional Theory (DFT) to study molecular adsorption and interactions. Her work involves conducting DFT calculations with software like VASP to understand how organic molecules interact with metal surfaces, which has implications for materials science and catalysis.

Professional Journey

Ameliaā€™s professional journey includes roles as a Research Assistant and Teaching Assistant. She has gained experience in conducting advanced research in computational chemistry and has taught introductory chemistry and analytical measurements laboratories. Her role as an REU participant at Coe College further expanded her expertise, where she worked on developing scintillating glass for high-energy applications.

Honors & Awards

Amelia has been recognized for her academic achievements, including receiving the American Chemical Society Award during her undergraduate studies. This award reflects her exceptional performance and potential in the field of chemistry.

Publications Noted & Contributions

Amelia has contributed to several notable publications. Her paper on the interaction of nitrobenzene with the Ag(111) surface, published in Surface Science, showcases her research skills and contributions to understanding molecular interactions at the atomic level. Her presentations at various American Chemical Society meetings and Schrƶdinger Educatorā€™s Week highlight her active engagement in the scientific community and her commitment to sharing knowledge and advancements in computational chemistry.

Sweet, A. K.; Mason, S. E. ā€œInsights into the Interaction of Nitrobenzene and the Ag(111) Surface: a DFT Studyā€. Surface Science, 2024, 122578. DOI: https://doi.org/10.1016/j.susc.2024.122578.

Sweet, A.; Duke, R. ā€œTeaching collaborative science: merging computational and physical chemistry alongside data science in the classroomā€. Virtual oral presentation at Schrƶdinger Educatorā€™s Week, June 2023.

Sweet, A.; Mason, S. E. ā€œAdsorption of Nitrobenzene to the Ag (111) Surfaceā€. Oral presentation at the Midwest Regional Meeting of the American Chemical Society, October 2022.

Sweet, A.; Mason, S. E. ā€œAdsorption of Nitrobenzene to the Ag (111) Surfaceā€. Oral presentation at the National Meeting of the American Chemical Society, August 2022.

Sweet, A.; Mason, S. E. ā€œAdsorption of Nitrobenzene to the Ag (111) Surface: A DFT Studyā€. Poster presentation at the National Meeting of the American Chemical Society, March 2022.

Research Timeline

Ameliaā€™s research timeline includes her current Ph.D. studies, ongoing since August 2020, and previous research experiences, such as her REU at Coe College and her research assistantship at the University of Iowa. Her timeline reflects a progressive development of expertise in computational chemistry, with significant contributions and advancements made throughout her academic career.

Collaborations and Projects

Amelia has collaborated with notable researchers such as Dr. Sara Mason and Dr. Scott Shaw on her Ph.D. research. Her projects include studying molecular adsorption using DFT and developing advanced materials for high-energy applications. Her collaborations extend to presenting joint research findings at major conferences and contributing to academic publications, demonstrating her ability to work effectively within a research team.

Strengths of the Best Researcher Award

High-Impact Research: Ameliaā€™s work on the adsorption of nitrobenzene to the Ag(111) surface has been published in a prominent journal, Surface Science, and has been well-received in the scientific community. This recognition indicates that her research addresses important questions in computational surface science.

Strong Academic Foundation: Her education in both undergraduate and graduate studies provides a robust background in chemistry. The combination of theoretical and practical experience positions her as a knowledgeable researcher capable of conducting significant studies in computational chemistry.

Active Engagement in Scientific Community: Amelia’s involvement in presenting her research at national and regional conferences, as well as her participation in virtual presentations at prominent events like Schrƶdinger Educatorā€™s Week, demonstrates her commitment to sharing knowledge and engaging with the scientific community.

Collaboration with Esteemed Researchers: Working with Dr. Sara Mason and Dr. Scott Shaw on her Ph.D. research has provided her with valuable mentorship and collaborative opportunities. These partnerships enhance the quality and impact of her research, reflecting positively on her achievements.

Recognition Through Awards: Receiving the American Chemical Society Award during her undergraduate studies highlights Amelia’s exceptional performance and potential in the field. Such accolades are indicative of her promising research career and contribute to her recognition as a leading researcher.

Areas for Improvement

Diversification of Research Topics: While Ameliaā€™s focus on nitrobenzene and Ag(111) surfaces is significant, expanding her research to include other molecules or surfaces could provide a broader impact and showcase versatility in computational chemistry.

Increase in Publication Volume: Although her publications are noteworthy, increasing the number of peer-reviewed articles could further enhance her visibility and influence in the field. More frequent publications could also reflect a higher research productivity.

Broaden Research Scope: Exploring additional computational methods or interdisciplinary approaches could enhance her research impact. Incorporating other computational techniques or collaborating with researchers in related fields might provide new insights and applications.

Grant Acquisition: Securing research grants and funding is crucial for expanding the scope of research. Seeking grants for specific projects or collaborative research could provide additional resources and support for her work.

Enhancing Public Engagement: Increasing efforts to engage with broader audiences through public science communication, media interactions, or educational outreach could enhance the societal impact of her research and raise her profile beyond academic circles.

Conclusion

Amelia Sweet’s achievements in computational chemistry and her recognition through the “Best Researcher Award” reflect her dedication and contributions to the field. Her strong academic background, impactful research, and active participation in the scientific community highlight her potential as a leading researcher. To further enhance her career, expanding her research topics, increasing publication volume, and seeking additional funding and public engagement opportunities will be beneficial. These steps can help Amelia build on her current successes and continue making significant contributions to computational chemistry.