Hossein Abdizadeh | Tissue Engineering Regeneration | Best Researcher Award

Published on by Cell Biologist

Prof. Dr. Hossein Abdizadeh | Tissue Engineering Regeneration | Best Researcher Award

University of Tehran | Iran

Hossein Abdizadeh is a leading researcher in the field of materials engineering, specializing in the synthesis of nano-materials, semiconductors, and nano-structured composites. His research emphasizes the fabrication, characterization, and functional optimization of advanced ceramic and composite materials. His doctoral work focused on the development and analysis of duplex alumina-based three-layer laminated composites, exploring their structural and mechanical properties. He also investigated surface hydroxyl groups in ceramic materials using infrared spectrometry during his postgraduate studies, contributing to a deeper understanding of surface chemistry in ceramics. Over his career, he has led multiple university and industry-collaborative research projects, advancing applications of nano-structured materials in engineering contexts. Abdizadeh has a prolific publication record, with over 156 papers in international journals, numerous national and international conference contributions, and a Farsi-language book on chemical methods for producing nanoparticles. In 2009, he established the Nano-structured Materials and Composites Laboratory at the University of Tehran, fostering experimental research in advanced composites, nanomaterials, and their applications in metallurgy and materials science. His work combines experimental synthesis, microstructural characterization, and the study of material properties to develop innovative solutions in materials engineering and nanotechnology.

Profiles: Google Scholar | Scopus

Featured Publications:

Abdizadeh, H., Ghelich, R., Farhangian, M., Akbari Asbagh, R., Ahmadi Tafti, S. M., Foroutani, L., Chehresonboll, Y., & Poopak, A. (2025). Bioactive chitosan/polycaprolactone cryogel sponge co-loaded with ciprofloxacin and ginger for controlled drug release and healing of infected wounds. Materials & Design.

Abdizadeh, H., Khodabandeh, F., & Golobostanfard, M. R. (2025). Decoration of ZnO nanorod arrays with heterojunction of graphene quantum dots and MoS2 nanoparticles for photoelectrochemical water splitting. Applied Energy Materials.

Abdizadeh, H., Bakhshaei, P., & Ataie, A. (2024). Facile mechanical fabrication of Cu-Ni/CNT nanocomposite for improved microstructural, hardness, and electrical characteristics. Institute of Materials, Minerals & Mining.

Abdizadeh, H., Khodabandeh, F., Abdollahi Avanaki, A., & Golobostanfard, M. R. (2024). Photoelectrochemical water splitting based on chalcopyrite semiconductors: A review. International Journal of Hydrogen Energy, 65, 779–803.

Abdizadeh, H., Ghorbani, M., Sheibani, S., & Golobostanfard, M. R. (2024). Efficient synthesis of recyclable porous BiFeO3/rGO thin film via sol-gel method as an enhanced photocatalyst. Colloids and Surfaces A: Physicochemical and Engineering Aspects, 686, 133429.

Abdizadeh, H., Beighi, M., Pourabdoli, M., & Raygan, Sh. (2023). Direct synthesis of tungsten carbide by solid‑state carbothermic reduction of tungsten trioxide. Transactions of the Indian Institute of Metals, 76(12), 3455–3461.

Zohreh Bagher | Tissue Engineering Regeneration | Best Researcher Award

Published on by Cell Biologist

Assoc. Prof. Dr. Zohreh Bagher | Tissue Engineering Regeneration | Best Researcher Award

Assoc. Prof. Dr. Zohreh Bagher | Iran University of Medical Sciences (IUMS) | Iran

Dr. Zohreh Bagher is an Associate Professor at the ENT and Head and Neck Research Center, Five Senses Health Institute, Iran University of Medical Sciences. She is an expert in tissue engineering and regenerative medicine with a strong background in anatomy and radiology. Her interdisciplinary research merges biomaterials, stem cells, and nanotechnology to develop innovative therapies for nerve and tissue repair. She has published extensively in high-impact journals on topics ranging from hydrogel scaffolds to nerve regeneration. With over a decade of experience, Dr. Bagher demonstrates exceptional leadership in biomedical engineering and translational medicine. Her work is pioneering in applying biomaterial science for clinical applications, particularly in wound healing, nerve injury, and tissue scaffolding. She actively collaborates internationally and integrates cutting-edge microfluidic and 3D-printing technologies into her research portfolio. Dr. Bagher’s commitment to science, education, and patient care positions her as a prime candidate for the Best Researcher Award.

Publication Profile: 

Scopus
Google Scholar

Education:

Dr. Bagher completed her Ph.D. in Tissue Engineering at Iran University of Medical Sciences, specializing in the differentiation of Wharton’s Jelly-derived mesenchymal stem cells into motor neuron-like cells using advanced PCL/collagen nanofibrous scaffolds. Her doctoral work emphasized combining biomaterials with stem cell therapy to regenerate nerve tissues, supervised by leading experts Prof. Joghataei and Prof. Mirzadeh. Prior to her Ph.D., she earned a Master’s degree in Anatomy from Qazvin University of Medical Sciences, focusing on bone repair through comparative studies using hydroxyapatite/β-tricalcium phosphate and xenograft scaffolds in animal models, guided by Prof. Rajaei. Her academic journey began with a Bachelor’s degree in Radiology from Tehran University of Medical Sciences, laying a solid foundation in medical imaging and diagnostics. This multi-disciplinary education has empowered her to innovate at the crossroads of biomedical engineering, anatomy, and regenerative medicine.

Experience:

Dr. Bagher holds a faculty position as Associate Professor at the ENT and Head and Neck Research Center, Iran University of Medical Sciences, where she spearheads cutting-edge research on biomaterials and tissue engineering. Over more than a decade, she has cultivated expertise in regenerative medicine, nerve repair, and scaffold fabrication. She has led numerous projects integrating microfluidics, 3D printing, and nanotechnology to engineer functional tissue substitutes. Her collaborative work spans experimental animal models and translational applications, emphasizing practical clinical outcomes. She has supervised multiple graduate students, fostering a research environment focused on innovation and scientific rigor. Dr. Bagher is also active in scientific publishing and peer review, contributing to advancing biomedical knowledge globally. Her interdisciplinary skills in anatomy, radiology, and tissue engineering, combined with leadership at a prestigious research center, make her a prominent figure in medical science and a deserving candidate for the Best Researcher Award.

Research Focus:

Dr. Bagher’s research centers on developing advanced biomaterials and stem cell-based therapies to promote tissue regeneration and nerve repair. Her work combines nanofibrous scaffolds, hydrogels, and bioactive composites designed to mimic natural extracellular matrices for enhanced cell differentiation and functional recovery. Key projects include engineering motor neuron-like cells from mesenchymal stem cells, fabricating injectable microparticles for drug delivery, and creating skin and nerve substitutes using 3D printing and crosslinked hydrogels. She explores the use of bioactive molecules like cannabidiol and copper oxide to stimulate angiogenesis and nerve regeneration. Her research also involves evaluating scaffold biocompatibility and mechanical properties, bridging lab-scale innovation with clinical relevance. By integrating tissue engineering with material science and pharmacology, Dr. Bagher aims to address unmet medical needs in wound healing, scar prevention, and peripheral nerve injury, driving forward personalized and regenerative medicine.

Publications Top Notes: 

  •  Fabrication of injectable dexamethasone-loaded hydrogel microparticle via microfluidic technique for biomedical applications

  •  Effectiveness of the injectable hyaluronic acid-based microparticles loaded with cannabidiol on rat sciatic nerve injury model

  •  Utilizing biomaterials for laryngeal respiratory mucosal tissue repair in an animal model

  •  A cellulose-based skin adhesive hydrogel incorporating N-acetyl-seryl-aspartyl-lysyl-proline peptide for enhanced wound healing and scar prevention in rabbit scar ear model in vivo

  •  Testicular extracellular matrix/gelatin-based scaffold using gas foaming to support spermatogonial stem cells

  •  Engineering of a CuO-Releasing 3D-Printed Bilayer Skin Substitute with Improved Angiogenesis: In Vitro and In Vivo Evaluations

  •  Correction: Graphene-Based Materials Prove to Be a Promising Candidate for Nerve Regeneration Following Peripheral Nerve Injury

  •  Vanadium ferrite-doped mesoporous bioactive glass-ceramics: controlled cisplatin delivery in chemohyperthermia

  • Photo- and thermal-crosslinked GelMA/chitosan hydrogels: A novel approach to enhanced mechanical and biological properties

Conclusion:

Dr. Zohreh Bagher is a highly accomplished researcher whose work sits at the forefront of regenerative medicine and biomaterials for clinical applications. Her multidisciplinary approach, innovative methodologies, and leadership in a specialized medical research center demonstrate exceptional qualifications for the Best Researcher Award. With minor enhancements in translational efforts and international visibility, she stands to further elevate her research impact. She is a deserving candidate who exemplifies excellence in scientific innovation and academic mentorship.

Slesha Tuladhar | Tissue Engineering Regeneration | Best Researcher Award

Published on by Cell Biologist

Ms. Slesha Tuladhar | Tissue Engineering Regeneration | Best Researcher Award

Ms. Slesha Tuladhar | Paramount Planet Product | United States

Slesha Tuladhar is a dynamic and multidisciplinary researcher specializing in sustainable materials and advanced manufacturing. Currently pursuing a Master of Science in Mechanical Engineering at the University of Maine, she brings a unique blend of technical expertise and creative thinking, thanks to her triple bachelor’s degrees in Sustainable Product Design, Architecture, and Business Administration from Keene State College. Her passion for innovation and sustainability is evident in her groundbreaking work with hydrogels and 3D bioprinting technologies. Slesha has published extensively in peer-reviewed journals and conferences, focusing on optimizing the rheological properties of bio-inks and cellulose-derived materials. She is actively involved in teaching and mentoring, and serves on the University of Maine’s Graduate Sustainability Committee. With numerous accolades, including National Science Foundation travel grants and leadership roles in academic organizations, Slesha stands out as a forward-thinking researcher poised to make significant contributions to the future of sustainable manufacturing.

Publication Profile:

Scopus

Education:

Slesha Tuladhar is currently a Master of Science candidate in Mechanical Engineering at the University of Maine, expecting to graduate . Her thesis focuses on “Free Hanging Hydrogel Droplet Formation for 3D Cell Culturing,” reflecting her deep engagement in biofabrication research. She holds three bachelor’s degrees from Keene State College, each earned with distinction (GPA: 4.0): Bachelor of Science in Sustainable Product Design and Innovation, Bachelor of Science in Architecture, and Bachelor of Science in Business Administration. Her academic path reflects a rare convergence of design, engineering, and business principles, positioning her to lead in both research and applied industry settings. Throughout her education, she has focused on sustainable solutions, material science, and advanced manufacturing technologies, particularly in the field of 3D bioprinting with cellulose-based hydrogels. This well-rounded and rigorous academic background lays the foundation for her impactful research contributions.

Experience:

Slesha has gained extensive hands-on research and teaching experience across both undergraduate and graduate levels. As a Research Assistant at the University of Maine, she investigates cellulose-based hydrogels, optimizing rheological properties for 3D bioprinting. She concurrently serves as a Teaching Assistant, supporting courses in Manufacturing and Materials Engineering. Here, she mentors students in processes including casting, molding, milling, forming, and additive manufacturing. Prior to this, at Keene State College, she led research projects on hybrid hydrogels, culminating in several peer-reviewed publications and conference presentations. Her work explored the integration of Tempo-Mediated Nanofiber Cellulose and Carboxymethyl Cellulose into bio-inks for sustainable manufacturing. Slesha has presented at national conferences, collaborated with faculty on high-level research, and led student organizations, including her role as President of the Society of Manufacturing Engineers. Her experience combines experimental rigor, educational impact, and leadership — all core qualities for a leading researcher.

Honors and Awards:

Slesha Tuladhar’s academic journey has been decorated with numerous honors and awards that reflect her excellence in research, leadership, and service. She is a two-time recipient of the prestigious National Science Foundation (NSF) student travel grant for her work on hydrogel-based bioprinting. At Keene State College, she was awarded the Peter Jenkins Memorial Scholarship Endowment, recognizing her academic distinction and research contributions. Slesha was also supported throughout her undergraduate career by the Little Sister’s Fund (LSF) Scholarship, awarded for outstanding potential and academic commitment. Her work has garnered attention across academic communities and the media, featured in outlets like New Hampshire Business Review, Union Leader, and the EPSCoR Idea Foundation. Additionally, she held leadership positions, including serving as President of the Society of Manufacturing Engineers and Graduate Student Senator at the University of Maine. These accolades underscore her potential as a transformative researcher and emerging leader in sustainable technologies.

Research Focus:

Slesha Tuladhar’s research lies at the intersection of material science, biofabrication, and sustainability. Her work focuses on the formulation and rheological optimization of hydrogel-based bio-inks, with a special emphasis on cellulose-derived polymers like Carboxymethyl Cellulose (CMC) and Tempo-Oxidized Nanofiber Cellulose (TONFC). She investigates how parameters like shear rate, solid content, and fiber integration impact 3D printability and scaffold fidelity, with applications in tissue engineering and sustainable manufacturing. Through her thesis on “Free Hanging Hydrogel Droplet Formation for 3D Cell Culturing,” she explores innovative methods for precision cell placement and viability. Her long-term vision involves developing biocompatible and environmentally sustainable materials that can replace synthetic polymers in biomedical and industrial applications. Her work contributes both theoretical insights (via rheological modeling) and practical methodologies (via extrusion-based bioprinting), making it impactful for academic, clinical, and commercial fields. She integrates engineering precision with ecological responsibility, aiming to reshape future manufacturing practices.

Publications Top Notes:

  1. Tuning Shear Thinning Factors of 3D Bio-Printable Hydrogels Using Short Fiber – Materials

  2. Controlling Rheological Properties of Hybrid Hydrogel Using Short Fiber for Extrusion-Based 3D Bioprinting – ASME MSEC

  3. Developing Hybrid Hydrogels for Full-Scale Scaffold Fabrication Using Extrusion-Based Bioprinting Process – ASME MSEC

  4. Pre-Crosslinked Hybrid Hydrogels for 3D Bio-Printing Process: Rheological Analysis – ASME MSEC

  5. Rheological Analysis of Low Viscosity Hydrogels for 3D Bio-Printing Processes – ASME MSEC

  6. Rheological Study of Highly Thixotropic Hydrogels for 3D Bio-Printing Processes – IIE Conference Proceedings

  7. Modulating Rheological Characteristics of Bio-Ink with Component Weight and Shear Rate for Enhanced Scaffold Fidelity – Bioprinting,  (Link Disabled)

  8. Fine-Tuning Rheological Properties of 3D Bio-Printable Hybrid Hydrogel by Controlling Component Solid Content – Conference Paper,
    (Additional journal titles not provided, assuming 12 total in the record)

Conclusion:

Slesha Tuladhar is an exceptional young researcher whose work stands at the intersection of sustainability, material science, and biofabrication. Her strong academic foundation, innovative research contributions, and proactive engagement in leadership and community roles present her as a well-rounded and highly deserving candidate for the Best Researcher Award. With a forward-thinking approach and dedication to solving real-world challenges through sustainable engineering, Slesha embodies the values and promise of future scientific leadership.

 

 

Raveendra Pilli | Tissue Engineering Regeneration | Best Researcher Award

Published on by Cell Biologist

Mr. Raveendra Pilli | Tissue Engineering Regeneration | Best Researcher Award

Mr. Raveendra Pilli , National Institute of technology-Silchar , India

Raveendra Pilli, a dedicated research scholar from Vijayawada, Andhra Pradesh, is currently pursuing a Ph.D. in Electronics and Communication Engineering at the National Institute of Technology Silchar, Assam. His research focuses on brain age prediction and early detection of neurological disorders using neuroimaging modalities. With extensive teaching experience, Raveendra has demonstrated excellence in course delivery, student mentoring, and research guidance. He has made significant contributions to his field through various high-impact publications, demonstrating a passion for integrating deep learning with brain health diagnostics. His goal is to bridge the gap between artificial intelligence and neuroscience, contributing to advancements in the early detection of neurological disorders such as Alzheimer’s and Parkinson’s diseases. His research continues to make strides in neuroimaging, deep learning, and medical diagnostics, earning recognition for its impact in both academia and healthcare.

Publication Profile:

Google Scholar

Strengths for the Award:

Raveendra Pilli has demonstrated remarkable academic and research achievements in the field of electronics and communication engineering, with a specific focus on brain age prediction and the early detection of neurological disorders through neuroimaging modalities. His extensive teaching experience at the undergraduate level and his current research in leveraging deep learning for brain health diagnostics highlight his strong commitment to both education and innovative research. He has published high-impact articles in renowned journals such as IEEE Transactions on Cognitive and Developmental Systems and Engineering Applications of Artificial Intelligence, with several more under review. His research is not only advancing the field of neuroimaging but also contributing significantly to healthcare, particularly in early diagnosis of diseases like Alzheimer’s and Parkinson’s. Raveendra’s use of deep learning to develop diagnostic biomarkers exemplifies his technical expertise and his ability to integrate complex methodologies into real-world applications.

Areas for Improvement:

While Raveendra has made substantial strides in his research, further collaboration with clinical and healthcare professionals could enhance the practical implementation of his findings. Building interdisciplinary networks with medical experts might provide valuable insights into the clinical validation and adoption of his research. Additionally, expanding the geographical and academic outreach of his research through more international collaborations and conference presentations would help strengthen his visibility and impact within the global research community.

Education:

Raveendra Pilli holds a Ph.D. in Electronics and Communication Engineering from the National Institute of Technology Silchar (2021–Present). His thesis focuses on leveraging deep learning techniques to establish the brain age gap as a diagnostic biomarker for neurological disorders. With an outstanding 9 CGPA, his academic journey has been marked by deep commitment to research and excellence. He completed his M.Tech. in Electronics and Communication Engineering from JNTU Kakinada in 2011, securing 76%. Prior to that, he earned a B.Tech. in the same discipline from JNTU Hyderabad in 2007, achieving a 65% score. Raveendra also excelled in his secondary and higher secondary education, with notable academic achievements. He qualified for the UGC NET examination as an Assistant Professor in 2019, further cementing his academic credentials and commitment to advancing education in electronics and communication engineering.

Experience:

Raveendra Pilli’s professional experience spans over a decade, with roles as a Senior Research Fellow and Junior Research Fellow at the National Institute of Technology Silchar, Assam, since 2021. He has supported faculty in delivering courses such as Digital Signal Processing and Basic Electronics, alongside mentoring undergraduate research projects. Previously, he worked as an Assistant Professor at SRK College of Engineering and Technology, Vijayawada (2012–2021), where he taught courses in Networks Theory, Digital Signal Processing, and Image Processing. He actively mentored students, guiding them toward academic success and research accomplishments. His teaching style includes innovative methods such as active learning to improve student engagement and learning outcomes. Raveendra’s combined teaching and research roles reflect his dedication to both educating the next generation of engineers and advancing the frontiers of research in his field, particularly in brain health and deep learning applications.

Research Focus:

Raveendra Pilli’s research focuses on the intersection of electronics, communication, and neuroscience, particularly in brain age prediction and the early detection of neurological disorders through neuroimaging modalities. His work leverages deep learning techniques to analyze brain structures and biomarkers, aiming to identify critical indicators for diseases like Alzheimer’s and Parkinson’s. He is dedicated to developing advanced methods for brain age estimation using multimodal neuroimaging, such as MRI and PET scans, combined with innovative machine learning models like deep learning and kernel regression networks. His research seeks to create diagnostic biomarkers that can be used in clinical settings for early detection and diagnosis. Raveendra’s contributions aim to improve the accuracy of neurological disorder detection, offering the potential to detect these conditions at earlier, more treatable stages. His expertise in neuroimaging, machine learning, and computational models positions him as a leading researcher in this emerging area.

Publications Top Notes:

  1. “Association of white matter volume with brain age classification using deep learning network and region-wise analysis” 🧠
  2. “Kernel Ridge Regression-based Randomized Network for Brain Age Classification and Estimation” 🔬
  3. “Brain Age Estimation Using Universum Learning-Based Kernel Random Vector Functional Link Regression Network” 🤖
  4. “Unveiling Alzheimer’s Disease through Brain Age Estimation Using Multi-Kernel Regression Network and MRI” 🧳
  5. “Multimodal neuroimaging based Alzheimer’s disease diagnosis using evolutionary RVFL classifier” 🧩
  6. “Investigating White Matter Abnormalities Associated with Schizophrenia Using Deep Learning Model and Voxel-Based Morphometry” 🧑‍🔬
  7. “Brain Age Estimation of Alzheimer’s and Parkinson’s Affected Individuals Using Self-Attention Based Convolutional Neural Network” 🧠
  8. “Brain Age Estimation Using Universum Learning-Based Kernel Random Vector Functional Link Regression Network” 📚

Conclusion:

Raveendra Pilli is an outstanding researcher with the potential to drive transformative change in the early detection and diagnosis of neurological disorders. His research has already made significant contributions to the application of deep learning in neuroimaging, and his future work promises to continue to push the boundaries of this emerging field. With his exceptional academic background, impressive publication record, and unwavering commitment to research, Raveendra is highly deserving of the Best Researcher Award.