Amir Zarebkohan | Nanomedicine | Best Researcher Award

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Dr. Amir Zarebkohan | Nanomedicine | Best Researcher Award

Tabriz University of Medical Sciences | Iran

Dr. Amir Zarebkohan’s research focuses on the development of advanced nanomedicine strategies for targeted drug delivery and cancer therapy. His work integrates medical nanotechnology and physiology to design innovative nanosystems capable of precise drug transport within biological environments. He specializes in smart targeted delivery platforms, nano–bio interface studies, and nano chemo-immunotherapy approaches aimed at improving therapeutic efficacy while minimizing systemic toxicity. His current projects involve the co-delivery of cyclophosphamide and HLH peptide using D8 and RIVAP-modified chitosan nanoparticles, engineered to respond to the redox conditions of the tumor microenvironment for glioma targeting in rat models. Additionally, he is developing chitosan-based nanoparticles containing dendrimers loaded with cyclophosphamide and sitagliptin, further functionalized with targeting ligands for enhanced delivery efficiency. His research emphasizes translational applications of nanotechnology in oncology and the exploration of biocompatible polymeric carriers for controlled and localized drug release. Through his studies, Dr. Zarebkohan contributes to advancing nano-chemoimmunotherapeutic platforms that bridge the gap between nanoscience and clinical medicine, offering potential breakthroughs in the treatment of complex and resistant cancers.

Profiles:  Google Scholar | Scopus | Orcid

Featured Publications:

Zarebkohan, A., & colleagues. (2024). Enhanced docetaxel therapeutic effect using dual targeted SRL-2 and TA1 aptamer conjugated micelles in inhibition Balb/c mice breast cancer model. Scientific Reports, 14, Article 75042.

Zarebkohan, A., & colleagues. (2024). Discovery of a novel dual targeting peptide for human glioma: From in-silico simulation to acting as targeting ligand. Advanced Pharmaceutical Bulletin, 14, Article 033.

Zarebkohan, A., & colleagues. (2023). Dual targeting salinomycin-loaded smart nano-micelles for enhanced accumulation and therapeutic outcome in breast cancer. International Journal of Pharmaceutics, 123095.

Zarebkohan, A., & colleagues. (2023). CDX-modified chitosan nanoparticles remarkably reduce therapeutic dose of fingolimod in the EAE model of mice. International Journal of Pharmaceutics, 122815.

Zarebkohan, A., & colleagues. (2023). Exosomal transmission of viruses, a two-edged biological sword. Cell Communication and Signalling, 21, Article 37.

Rosa M Giraldez-Perez | Intracellular Transport Systems | Innovative Research Award

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Prof. Dr. Rosa M Giraldez-Perez | Intracellular Transport Systems | Innovative Research Award

University or Cordoba | Spain

Rosa María Giráldez-Pérez is a researcher in the fields of nanotechnology, nanomedicine, physiology, and neuroscience whose scientific contributions focus on the design and application of nanomaterials for therapeutic purposes. Her work has addressed innovative strategies such as gold nanosystems functionalized with antibiotics or anticancer drugs, the development of nanocarriers for leukemia, prostate, liver, and lung cancer treatments, as well as nanoparticle-based approaches to prevent antibiotic resistance. She has also contributed to research in obesity therapy through nanosystems targeting metabolic regulation and in neuroscience through studies on oxidative stress and fragile X syndrome. Her research output includes 81 scientific documents, which have accumulated 911 citations and reflect an h-index of 13, demonstrating both productivity and impact in her field. A significant portion of her publications are in high-impact journals indexed in the Journal Citation Reports (JCR), and several list her as first or senior author, highlighting her leading role in collaborative projects. By integrating expertise from cellular biology, physiology, and nanoscience, her work advances translational biomedical research and offers potential therapeutic solutions for cancer, infectious diseases, metabolic disorders, and neurological conditions.

Profiles: Orcid | Scopus

Featured Publications:

Giráldez-Pérez, R. M., Grueso, E. M., Montero-Hidalgo, A. J., Muriana-Fernández, C., Kuliszewska, E., Luque, R. M., & Prado-Gotor, R. (2025). Daunomycin nanocarriers with high therapeutic payload for the treatment of childhood leukemia. Pharmaceutics, 17(9), 1236.

De Diego-Otero, Y., El Bekay, R., García-Guirado, F., Sánchez-Salido, L., & Giráldez-Pérez, R. M. (2024). Apocynin, a selective NADPH oxidase (Nox2) inhibitor, ameliorates behavioural and learning deficits in the fragile X syndrome mouse model. Biomedicines, 12(2887).

Lhamyani, S., Gentile, A. M., Mengual-Mesa, M., Grueso, E., Giráldez-Pérez, R. M., Fernandez-Garcia, J. C., … El Bekay, R. (2024). Au@16-pH-16/miR-21 mimic nanosystem: An efficient treatment for obesity through browning and thermogenesis induction. Biomedicine & Pharmacotherapy, 171, 116104.

Giráldez-Pérez, R. M., Grueso-Molina, E. M., Carbonero-Martínez, A., Álvarezmárquez, J., Kuliszewska, E., Gordillo-Macías, M., & Prado-Gotor, R. (2023). Synergistic antibacterial effects of amoxicillin and gold nanoparticles: A therapeutic option to combat antibiotic resistance. Antibiotics, 12(8), 81275.

Giráldez-Pérez, R. M., Grueso, E., Montero-Hidalgo, A. J., Luque, R. M., Carnerero, J. M., Kuliszewska, E., & Prado-Gotor, R. (2022). Gold nanosystems covered with doxorubicin/DNA complexes: A therapeutic target for prostate and liver cancer. International Journal of Molecular Sciences, 23(24), 15575.

Giráldez-Pérez, R. M., Grueso, E. M., Jiménez-Aguayo, R., Carbonero, A., González-Bravo, M., Kuliszewska, E., & Prado-Gotor, R. (2022). Use of nanoparticles to prevent resistance to antibiotics: Synthesis and characterization of gold nanosystems based on tetracycline. Pharmaceutics, 14(9), 1941.

Lhamyani, S., Gentile, A. M., Giráldez-Pérez, R. M., et al. (2021). miR-21 mimic blocks obesity in mice: A novel therapeutic option. Molecular Therapy – Nucleic Acids, 26, 401–416. h

Grueso-Molina, E. M., Giráldez-Pérez, R. M., Kuliszewska, E., Guerrero, J. A., & Prado-Gotor, R. (2021). Reversible cationic gemini surfactant-induced aggregation of anionic gold nanoparticles for sensing biomolecules. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 610, 125893.

Gomes, A., Carnerero-Panduro, J. M., Jiménez-Ruiz, A., Grueso-Molina, E. M., Giráldez-Pérez, R. M., & Prado-Gotor, R. (2021). Lysozyme-AuNPs interactions: Determination of binding free energy. Nanomaterials, 11(8), 2139.

Giráldez-Pérez, R. M., Grueso-Molina, E. M., Domínguez-García, I., Pastor-Carrillo, N. M., Kuliszewska, E., & Prado-Gotor, R. (2021). Biocompatible DNA/5-fluorouracil gemini surfactant-functionalized gold nanoparticles as promising vectors in lung cancer therapy. Pharmaceutics, 13(3), 423.

Abbas Montayeri | Tissue Engineering Regeneration | Best Researcher Award

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Assoc. Prof. Dr. Abbas Montayeri | Tissue Engineering Regeneration | Best Researcher Award

Assoc. Prof. Dr. Abbas Montayeri | K N Toosi University of Technology | Iran

Dr. Abbas Montazeri is an Associate Professor in the Faculty of Materials Science and Engineering at K.N. Toosi University of Technology, Tehran, Iran. With over a decade of academic and research experience, Dr. Montazeri specializes in molecular dynamics simulations, computational nanomechanics, and multiscale modeling. He received his Ph.D. in Nanotechnology from Sharif University of Technology, where he also completed his M.Sc. and B.Sc. in Mechanical Engineering. A resident researcher at IPM and director of graduate studies at KNTU, he has led pioneering work in biological nanocomposites, heat transfer at the nanoscale, and drug delivery systems. Dr. Montazeri’s contributions are widely recognized through numerous journal publications, a book chapter, and multiple national awards. His interdisciplinary work bridges fundamental simulation techniques and real-world applications, notably in advanced materials and biomedical engineering. He continues to mentor students and contribute actively to cutting-edge nanotechnology research.

Publication Profile:

Orcid

✅ Strengths for the Award:

  1. Outstanding Research Output: Dr. Montazeri has an impressive list of publications in top-tier international journals, demonstrating sustained and high-quality contributions to fields such as molecular dynamics, computational nanomechanics, and biomedical nanocomposites.

  2. Interdisciplinary Expertise: His research covers a diverse array of modern scientific domains, including drug delivery systems, nano-tribology, heat transfer at the nanoscale, and 2D nanostructures, highlighting his adaptability and scientific breadth.

  3. Innovative Methodologies: Use of MD simulations, data-driven modeling, and multiscale approaches showcases cutting-edge methodology with practical implications in biomedical engineering and materials science.

  4. Academic Leadership: Holding key positions such as Director of Graduate Studies and Vice-Chairman for Educational Affairs, he shows commitment not only to research but also to educational excellence and mentorship.

  5. National Recognition: Previous awards (e.g., Distinguished Young Researcher, Exceptional Talent Award) and top national ranks confirm his academic excellence and early recognition in the scientific community.

🛠️ Areas for Improvement:

  1. International Collaboration & Visibility: While publication quality is high, increased collaborations with international institutions could broaden the global impact and citation footprint.

  2. Patent or Industry Linkage: There’s no mention of technology transfer, industrial projects, or patents. Involving industry could enhance real-world application and innovation.

  3. Outreach & Public Engagement: Enhanced visibility through public lectures, conference keynote roles, or scientific community leadership would strengthen the public and academic profile.

🎓 Education:

Dr. Abbas Montazeri holds a distinguished academic record from Sharif University of Technology. He earned his Ph.D. in Nanotechnology/NanoMechanics from the Institute for Nano Science and Technology (2005–2010), where he focused on atomistic simulations and nanostructures. Before that, he completed his M.Sc. in Mechanical Engineering/Applied Design (2002–2004), working on solid mechanics and material behavior. His academic journey began with a B.Sc. in Mechanical Engineering/Solid Mechanics (1998–2002), during which he ranked 22nd nationally among nearly 250,000 candidates. His academic path reflects a steady progression into highly specialized research areas in nanomechanics and computational materials science. Throughout his education, Dr. Montazeri demonstrated academic excellence, receiving exceptional talent awards and high ranks in national entrance exams. His robust educational background laid the foundation for his interdisciplinary research in mechanical engineering, materials science, and biomedical applications.

💼 Professional Experience:

Dr. Montazeri has accumulated extensive professional experience in academia and research. He began his academic career as an Assistant Professor at K.N. Toosi University of Technology in 2012 and was promoted to Associate Professor in 2017. Concurrently, he has served in several administrative roles, including Vice-Chairman of Educational Affairs, Head of Divisions, and currently, Director of Graduate Studies at the Faculty of Materials Science and Engineering. Additionally, he has been a Resident Researcher at the School of Nano Science, IPM, since 2012. These roles reflect his leadership, commitment to education, and continuous contributions to nanotechnology research. His experience spans advanced computational modeling, educational management, and interdisciplinary collaboration. Dr. Montazeri has mentored numerous graduate students and has been instrumental in integrating simulation-based research with practical engineering applications, including drug delivery, tissue engineering, and nano-enabled sensors.

🏆 Awards and Honors:

Dr. Abbas Montazeri has received several prestigious awards that highlight his academic excellence and research contributions. In 2017, he was named a Distinguished Young Researcher at K.N. Toosi University of Technology. His Ph.D. thesis was selected as one of the best at the 7th Iranian Students Nanotechnology Conference in 2010. He was also honored with the Exceptional Talents Award by Sharif University’s Graduate Office in 2006. Early in his academic journey, Dr. Montazeri achieved remarkable ranks in competitive national exams: 20th place in the nationwide graduate entrance exam (2002) and 22nd place in Iran’s university entrance exam (1998) among hundreds of thousands of students. These accolades reflect a consistent pattern of high performance, innovation, and leadership in research and academia. His honors not only recognize past achievements but also underscore his ongoing contributions to materials science, computational mechanics, and nanotechnology.

🔬 Research Focus:

Dr. Montazeri’s research is at the forefront of computational materials science and nanotechnology. His work primarily involves Molecular Dynamics (MD) Simulation, NanoTribology, and Multiscale Modeling Techniques. He applies these methods to study biological nanocomposites for tissue engineering, heat transfer at the nanoscale, drug delivery systems, and 2D nanostructures. A strong focus of his research lies in understanding the mechanical, thermal, and interfacial behavior of materials at the atomic scale. His investigations into nanostructured composites, smart polymers, and surface-functionalized materials have opened new pathways in biomedical applications, especially in therapeutic implants and biosensors. He has also explored sintering processes, failure mechanisms, and data-driven modeling of nanomaterials. Dr. Montazeri’s interdisciplinary approach effectively bridges fundamental theoretical modeling with practical engineering challenges, making significant contributions to both academic literature and industrial innovation in advanced material systems.

📚 Publication Top Notes:

  • 🧪 Theoretical Modeling of CNT-Polymer Interactions – Elsevier Book Chapter (2017)

  • 💊 Molecular dynamics simulation reveals the reliability of Brij-58 nanomicellar drug delivery systems – J. Mol. Liquids, 2022

  • 🧱 Mechanical properties affected by coalescence mechanisms during Al-Cu nanoparticle sintering – Powder Tech, 2022

  • 🧩 Toughening role of surface-treated BN nanosheets in PLA nanocomposites – Eur. Polymer J., 2022

  • 🧪 Failure mechanisms in degraded hybrid composites via acoustic emission analysis – Eng. Failure Analysis, 2022

  • 🧬 Shape memory properties of graphene/polymer nanocomposites – Smart Mater. Struct., 2022

  • 🔬 Optimal sample location in quartz tuning fork biosensors – Biomedical Phys. Eng. Express, 2021

  • 🔥 Temperature-dependent sintering of metal nanoparticles – Powder Tech, 2021

  • 🧷 Adhesion in poly(L-lactic acid)/graphene nanocomposites via end-grafted polymers – Eur. Polymer J., 2021

  • 🌡️ Interfacial thermal conductance in functionalized BN/PLA nanocomposites – Prog. Organic Coatings, 2024

  • 📊 Predicting mechanical properties of defective h-BN nanosheets using data-driven models – Comput. Mater. Sci., 2023

  • ⚙️ Strain-rate plasticity of Ta-Cu nanocomposites for implants – Sci. Reports, 2023

  • 🦷 Mechanical properties of Ta/Cu nanocomposite dental implants – Metals and Mater. Int., 2023

  • 🧬 Neck growth and tensile properties in sintered Al-Cu systems via MD simulation – Adv. Powder Tech, 2023

🧾 Conclusion:

Dr. Abbas Montazeri is a highly qualified and deserving candidate for the Best Researcher Award. His rich research portfolio, technical depth, and consistent academic leadership position him as a leader in computational materials science and nanotechnology. While increasing international partnerships and industry engagement could further amplify his impact, his current accomplishments reflect a strong and balanced research profile that has significantly advanced both fundamental knowledge and applied science in nanomechanics and biomaterials.