Lin Wu | Bone Tissue Engineering | Excellence in Research Award

Published on by Cell Biologist

Ms. Lin Wu | Bone Tissue Engineering | Excellence in Research Award

Department of Stomatology, Shengjing Hospital of China Medical University, Shenyang, Liaoning, P.R | China

Professor Wu Lin is a leading scholar in oral rehabilitation and biomaterials research, recognized for her extensive contributions to bone implant materials and advanced technologies for dental restoration. Her work spans more than 90 peer-reviewed publications across high-impact national and international journals, reflecting sustained productivity and influence in stomatology research. She has led major scientific initiatives, including national natural science projects, a “14th Five-Year Plan” National Key R&D project, national disaster-related research, multiple sub-projects under the national “863” Plan, and several provincial-level grants. As the first inventor, she holds two authorized invention patents that advance the design and performance of oral implant systems. Her editorial roles in multiple scientific journals and participation in specialized professional committees further demonstrate her leadership in shaping research directions in oral medicine, prosthodontics, and biomaterials science. Through her innovations, Professor Wu has significantly advanced clinical applications and material technologies in modern stomatology.

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Featured Publications

Jeonghyun Kim | Cell Biomechanics | Research Excellence Award

Published on by Cell Biologist

Assoc. Prof. Dr. Jeonghyun Kim | Cell Biomechanics | Research Excellence Award

Kyushu University | Japan

Jeonghyun Kim’s research centers on mechanobiology and bioengineering, focusing on the interplay between mechanical forces and cellular function in tissue regeneration. His work explores mechanotransduction in osteocytes using advanced three-dimensional culture models, providing insights into how physical stimuli influence bone formation and remodeling. He has developed innovative hydrostatic pressure bioreactors to promote osteogenesis, contributing to bone regenerative strategies. In tissue engineering, he investigates the application of endometrial stromal cells in engineered constructs to enhance uterine regeneration and support early embryo implantation, bridging fundamental mechanobiology with translational regenerative medicine. His earlier studies examined the effects of hydrostatic pressure on chondrogenesis, elucidating mechanotransduction pathways critical for cartilage formation. Kim integrates computational modeling with experimental approaches, including finite element analysis, to optimize scaffold designs and predict cellular responses to mechanical stimuli. His research has been recognized with multiple awards, highlighting contributions to bioengineering and mechanobiology. Ongoing projects aim to dissect cellular responses under mechanical loading and improve tissue-engineered constructs for clinical applications. Through interdisciplinary approaches combining mechanical engineering, cell biology, and regenerative medicine, his work advances understanding of how mechanical environments guide tissue development and repair, with implications for musculoskeletal, reproductive, and cartilage regenerative therapies.

Profile: Orcid

Featured Publications: 

Inagaki, T., Kim, J.*, Maeda, E., Adachi, T., & Matsumoto, T. (2025). Macroscopic and microscopic biomechanical analysis of mineralized spheroids derived from human mesenchymal stem cells. Journal of Biomechanics.

Kim, J., Nagashima, S., Wang, J., Matsubara, S., Maeda, E., Okumura, D., & Matsumoto, T. (2025). Hierarchical wrinkle pattern drives tenogenic differentiation from human mesenchymal stem cells. Proceedings of the Institution of Mechanical Engineers, Part H: Journal of Engineering in Medicine, 239(10), 1000–1009.

Shinokawa, K., Sugawara-Narutaki, A., Kim, J., Matsumoto, T., & Maeda, E. (2025). A novel method to fabricate elastin/collagen fiber composites: Proof of concept. Materials Letters: X, 26, 100255.

Kamiya, T., Ito, Y., Iwasaki, T., Suzuki, D., Hayashi, T., Kim, J., Matsumoto, T., & Maeda, E.* (2025). Structural characterisation of newt tendon regeneration after complete transection: In vivo two-photon imaging and transmission electron microscopy. Journal of Anatomy.

Wang, J., Kim, J., Maeda, E., & Matsumoto, T.* (2025). An osteoblast-like cell line derived from mice expressing FRET-based tension sensor reveals cellular tension increase during osteogenic differentiation. Biochemistry and Biophysics Reports, 43, 102131.

Suzuki, S., Imajo, K., Wang, J., Kim, J., Maeda, E., Nagayama, K., & Matsumoto, T.* (2025). Orthogonal alignment of multilayered MC3T3-E1 cells induced by cyclic stretch. Biomechanics and Modeling in Mechanobiology.

Ohashi, Y., Suzuki, T., Iwasaki, T., Goto, K., Kim, J., Matsumoto, T., Saeki, M., & Maeda, E.* (2025). Quasi-static and dynamic mechanical properties of artificial tissue fabricated from concentrated collagen using mechano-chemical treatment. Materials Today Communications, 46, 112498.

Masuda-Otsuka, Y., Kamiya, T., Suzuki, D., Hayashi, T., Iwasaki, T., Kim, J., Matsumoto, T., & Maeda, E.* (2025). Biomechanical properties of regenerated digital flexor tendon in immature newt following complete transection. Bio-medical Engineering and Materials, 36(6), 335–342.

Kim, J.*, Niioka, K., Maeda, E., & Matsumoto, T. (2025). Application of hydrostatic pressure up-regulates Sost gene expression in osteocytic spheroid. Bioscience, Biotechnology, and Biochemistry, 89(2), 263–267. cellular biomechanics

Inagaki, T., Kim, J.*, Maeda, E., & Matsumoto, T. (2025). Macroscopic creep behavior of spheroids derived from mesenchymal stem cells under compression. Journal of the Mechanical Behavior of Biomedical Materials, 161, 106816.

Kavosh Zandsalimi | Skin Regeneration | Best Researcher Award

Published on by Cell Biologist

Dr. Kavosh Zandsalimi | Skin Regeneration | Best Researcher Award

Medical Laser Research Center, Yara Institute, ACECR, Tehran | Iran

Dr. Kavosh Zandsalimi is a biomedical engineer specializing in biomaterials and tissue repair technologies, with extensive expertise in the design, synthesis, and characterization of advanced biomaterials for biomedical applications. His research focuses on hydrogels, sponges, films, and micro/nanofibers, with particular emphasis on drug delivery systems, including hydrogels, nanofibers, microspheres, and metal-organic frameworks (MOFs). He has developed and optimized strategies for evaluating biomaterials in vitro, including cytotoxicity assessment, and antibacterial and anti-inflammatory efficacy. Dr. Zandsalimi’s work integrates nanomaterials synthesis with biomedical applications, aiming to enhance wound healing and tissue repair outcomes. He has successfully led projects that bridge fundamental research with translational applications, securing competitive research funding and mentoring teams in national and international innovation competitions. His research contributions extend to the development of protocols aligned with Good Laboratory Practice (GLP) and cleanroom standards, ensuring high-quality, reproducible results. Additionally, he has contributed to training programs on laboratory safety, biomaterials handling, and regulatory standards, reflecting his commitment to advancing both scientific knowledge and professional expertise in the biomedical engineering field.

Profiles: Google Scholar | Scopus

Featured Publications:

Heidari, B., Shams, S., Akbari, N., & Zandsalimi, K. (2025). Three-dimensionally decellularized human amniotic membrane scaffold: Structure, processing, and biological properties. Cell and Tissue Banking, 19(2), 2–47.

Karimi, M., Heidari, B., Jafary, H., & Zandsalimi, K. (2025). The quality and quantity of nanoparticles extracted from human adipose tissue derived-mesenchymal stem cells. Avicenna Journal of Medical Biotechnology, 17(3), 186–195.

Khorsandi, K., Hosseinzadeh, R., Esfahani, H., Zandsalimi, K., Shahidi, F. K., & Abrahamse, H. (2022). Accelerating skin regeneration and wound healing by controlled ROS from photodynamic treatment. Inflammation and Regeneration, 42(1), 40.

Talabani, R. M., Garib, B. T., Masaeli, R., Zandsalimi, K., & Ketabat, F. (2021). Biomineralization of three calcium silicate-based cements after implantation in rat subcutaneous tissue. Restorative Dentistry & Endodontics, 46(1).

Zandsalimi, K., & Akbari, B. (2021). Improving the mechanical properties of polyetheretherketone (PEEK) using organophilic montmorillonite for the manufacture of orthopedic and dental implants. In National Conference of Modern Materials (pp. 1–8).

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.