Yuxin Peng | Cell Adhesion Mechanisms | Best Researcher Award

Prof. Yuxin Peng | Cell Adhesion Mechanisms | Best Researcher Award

Prof. Yuxin Peng | Zhejiang University | China

Dr. Yuxin Peng is a distinguished researcher and educator in the field of biomedical and exercise science engineering. Currently serving as a ZJU 100 Young Professor at Zhejiang University, China, he has made significant strides in developing flexible sensors, smart wearable systems, and human–machine interaction technologies. With a Ph.D. and postdoctoral training at the National University of Singapore, his research integrates cutting-edge materials science, biomechanics, and AI-driven health monitoring systems. His work has been consistently published in high-impact journals like Science Advances, Advanced Science, IEEE Transactions, and Soft Robotics, reflecting both depth and innovation. Dr. Peng’s contributions are not only academic but also practical, with several of his innovations applied in rehabilitation, sports science, and robotics. His dedication and cross-disciplinary expertise make him a strong candidate for recognition such as the Best Researcher Award.

Publication Profiles: 

Orcid
Scopus

Education:

Dr. Yuxin Peng received his doctoral degree (Ph.D.) in an engineering-related discipline, laying a strong foundation in biomedical engineering, biomechanics, and sensor technologies. His early academic pursuits were rooted in multidisciplinary innovation, merging engineering principles with human physiology and robotics. To further deepen his scientific understanding, he pursued postdoctoral research at the prestigious National University of Singapore, focusing on biomedical systems and smart rehabilitation. During his academic training, Dr. Peng built expertise in wearable sensors, motion tracking systems, and soft robotics—technologies that play a crucial role in personalized healthcare and intelligent rehabilitation. His education trajectory demonstrates both depth and diversity, preparing him to address complex biomedical challenges with integrated, high-tech solutions. It also laid the groundwork for his future leadership roles and impactful research career at Zhejiang University, where he now mentors young researchers and leads innovation in health engineering.

Experience:

Dr. Yuxin Peng has built an impressive academic and research career spanning over a decade. He has been a ZJU 100 Young Professor at Zhejiang University, affiliated with the Institute of Exercise Science and Health Engineering. In this role, he leads interdisciplinary research projects in wearable technology, flexible sensors, and human motion analysis. Prior to this, he served as a Research Fellow at the Department of Biomedical Engineering, National University of Singapore, where he focused on intelligent health systems and rehabilitation technologies. His hands-on experience in global, high-tech research environments has allowed him to develop collaborations with experts in robotics, materials science, and medical engineering. He has supervised numerous projects and students, while continuously publishing in high-impact journals. His experience demonstrates a rare blend of academic rigor and real-world application, making him a leader in human-centered biomedical innovation and smart rehabilitation systems.

Research Focus:

Dr. Yuxin Peng’s research focuses on wearable systems, smart sensors, soft robotics, and biomedical signal processing for human motion monitoring and rehabilitation. His work addresses real-world problems such as gait analysis, joint motion detection, force sensing, and rehabilitation assistance. By integrating AI, flexible electronics, and biocompatible materials, he develops high-performance sensors and intelligent exosuits for applications in sports science, elderly care, and physical therapy. Notable innovations include graphene-based aerogels, hydrogel biosensors, and multi-feature neural networks for gesture recognition. His lab has also contributed to optical waveguide sensors, virtual reality rehabilitation, and MI-controlled exoskeletons. The overarching goal of his work is to enable non-invasive, real-time, and personalized health monitoring through smart technology. By pushing the boundaries of soft, adaptive, and human-interactive systems, Dr. Peng’s research is at the forefront of the next generation of intelligent biomedical engineering solutions.

Publications Top Notes:

  1. Hydroplastic Foaming of Graphene Aerogels and AI Tactile SensorsScience Advances

  2. Underwater Instant Adhesive Hydrogel Interfaces for Robust BiosensingAdvanced Science

  3. Flexible Segmented Assemblable Fiber Optic Sensor for Multi-Joint MonitoringSoft Robotics (Accepted)

  4. Calibration-Free Optical Waveguide Bending Sensor for Soft RobotsSoft Science

  5. Distributed Plantar 3D Force Measurement SystemSensors and Actuators A

  6. Superelastic Graphene Nanofibrous Aerogels for Intelligent Sign LanguageSmall

  7. Omnidirectional Soft Bending Sensor for Joint MonitoringIEEE TIE

  8. Shank-RIO: Ranging-Inertial Odometry for Gait and PositioningIEEE TIM

  9. Exosuit with Bidirectional Hand Support via Gesture RecognitionIEEE TNSRE

  10.  Advances in Flexible Bending Sensors and ApplicationsIJ Smart & Nano Materials

Conclusion:

In conclusion, Dr. Yuxin Peng exhibits all the qualities of a top-tier, award-worthy researcher. His work is characterized by scientific rigor, high-impact publication, and a vision for solving real-world healthcare challenges using cutting-edge sensor and robotics technologies. As a respected academic at Zhejiang University with a solid international research background, Dr. Peng has already contributed significantly to wearable health tech and rehabilitation sciences. His ability to combine soft material innovation, artificial intelligence, and biomechanics into novel human-machine interaction systems places him at the forefront of biomedical engineering research. While there is room for growth in the areas of commercialization and global academic engagement, his career trajectory, research excellence, and societal relevance of his innovations make him a highly deserving candidate for the Best Researcher Award.

Allegra Wundersitz | Signal Transduction Mechanisms | Young Scientist Award

Mrs. Allegra Wundersitz | Signal Transduction Mechanisms | Young Scientist Award

Mrs. Allegra Wundersitz , RWTH Aachen University, Molekulare Ökologie der Rhizosphäre , Germany

Allegra Wundersitz is a passionate molecular biologist currently pursuing her PhD at RWTH Aachen University, Germany, in the group of Molecular Ecology of the Rhizosphere. Her research delves into the molecular mechanisms of plant oxygen sensing and the regulatory role of acyl-CoA-binding proteins (ACBPs) in stress signaling. Allegra has been recognized for her academic excellence, receiving the ISPA Poster Award and the Best Botanic Master’s Thesis Award from the German Society for Plant Sciences (DBG). With expertise in cloning, yeast-two-hybrid, luciferase complementation, and computational modeling, she seamlessly integrates biochemical and molecular approaches. Allegra actively collaborates with interdisciplinary teams, bridging plant physiology, structural biology, and molecular dynamics. Her commitment to research and mentoring makes her a promising young scientist aiming to contribute not only to fundamental plant science but also to translational applications in health and agriculture.

Publication Profile:

Orcid

✅ Strengths for the Award:

  • Innovative Research Focus: Allegra’s work on acyl-CoA-binding proteins (ACBPs) in plant oxygen sensing and stress signaling demonstrates high originality. Her approach of integrating protein biochemistry, gene regulation, and computational modeling is both novel and impactful.

  • Early Recognition: Despite being in the early stages of her career, she has received notable honors, including the ISPA Poster Award and the Best Master’s Thesis Award (DBG)—highlighting the quality and relevance of her work.

  • Interdisciplinary Collaboration: She engages with experts in molecular dynamics and structural biology, enriching her research with advanced modeling of protein mutations—showing strong collaborative and technical competencies.

  • Mentorship & Leadership: Supervising undergraduate students showcases her commitment to academic development and science communication.

  • Publication Record: Her first peer-reviewed article in New Phytologist indicates strong potential for growing her scientific influence.

🧩 Areas for Improvement:

  • Professional Engagement: Joining relevant scientific societies or organizations could enhance her visibility, offer networking opportunities, and provide access to grants or awards.

  • Industry Exposure: While her current focus is on basic science, even limited engagement with applied research or biotechnology partnerships could broaden the translational scope of her work.

  • Publication Volume: As her research matures, expanding her publication record beyond reviews into primary experimental studies will strengthen her academic profile.

🎓 Education:

Allegra Wundersitz holds a Master’s degree in Plant Molecular Biology, where her thesis on acyl-CoA-binding proteins (ACBPs) earned national recognition by the German Society for Plant Sciences in 2024. She is currently a PhD student at RWTH Aachen University, Germany, specializing in the molecular ecology of the rhizosphere. Her academic training spans core fields such as structural biochemistry, plant physiology, and gene regulation. Through hands-on learning and international workshops, she has developed technical proficiency in protein interaction assays, biosensor design, and in silico modeling. Her education emphasizes a multidisciplinary approach, blending experimental and computational biology. She has also supervised undergraduate research projects, further strengthening her academic leadership. Allegra’s educational journey reflects her deep curiosity for understanding molecular mechanisms in plant biology and their broader implications.

🧪 Experience:

Allegra’s experience is rooted in academic molecular biology research. During her Master’s and now as a PhD candidate, she has completed two significant research projects: developing plant-based oxygen biosensors and exploring the role of ACBPs in gene regulation. Her current PhD project investigates how ACBPs act as acyl-CoA receptors, mediating responses to oxygen and stress in plants. She employs techniques such as yeast two-hybrid assays, luciferase complementation, cloning, and molecular modeling. Allegra has also collaborated with experts in molecular dynamics, including Prof. Maria Fyta and Dr. Chandan Das, to simulate structural effects of ACBP mutations. She has presented her work at international conferences and received a prestigious poster award at ISPA. Allegra is gaining valuable teaching experience through undergraduate supervision, making her a well-rounded early-career scientist. Though she has not yet worked in industry, her work holds potential translational value in agriculture and health.

🔍 Research Focus:

Allegra’s research centers on the role of acyl-CoA-binding proteins (ACBPs) as key molecular players in plant oxygen sensing and stress signaling. She investigates how ACBPs function as acyl-CoA receptors and modulate gene expression through dynamic protein-protein interactions. Her goal is to uncover how lipid signals like acyl-CoAs are translated into physiological responses under stress conditions. Using a combination of experimental techniques—such as cloning, luciferase complementation assays, yeast-two-hybrid screens—and computational molecular dynamics, she deciphers the structural and functional aspects of ACBP interactions. Her research not only expands fundamental plant molecular biology but also contributes insights with potential applications in crop resilience, metabolic regulation, and even human health, given ACBPs’ links to cancer and metabolic disorders. Through interdisciplinary collaboration, Allegra aims to bridge structural biochemistry and plant physiology to understand how cells adapt to fluctuating oxygen and energy levels.

📚 Publications Top Notes:

  • 🧬 Acyl-CoA-binding proteins: bridging long-chain acyl-CoA metabolism to gene regulationTansley Insight, New Phytologist (April 22, 2025)

🧾 Conclusion:

Allegra Wundersitz is a highly promising young researcher who combines technical excellence, creativity, and interdisciplinary integration in her approach to plant molecular biology. Her foundational work on ACBPs not only deepens our understanding of plant stress responses but also hints at broader implications in health and metabolic research. With her trajectory and dedication, she is an ideal candidate for the Young Scientist Award, and this recognition would further support her impactful scientific journey.