Wei Zhou | Engineering | Best Researcher Award

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Dr. Wei Zhou | Engineering | Best Researcher Award

Lecturer at Nanjing University of Information Science and Technology, China

Wei Zhou is an innovative researcher and lecturer at Nanjing University of Information Science and Technology, China. He specializes in automatic sleep stage scoring, with a particular focus on applying machine learning and artificial intelligence techniques to the field of sleep analysis. Zhou’s work addresses critical challenges in the field, such as the inconsistency of device signals and the presence of noise in data, by developing novel algorithms that enhance sleep stage classification. His research is methodologically rigorous and demonstrates a strong commitment to advancing the capabilities of sleep analysis systems. Zhou is passionate about integrating cutting-edge technologies with modern research methodologies to solve complex problems in biomedical engineering. His research has been published in prestigious journals, and his innovative approaches have made a significant impact on both academic studies and potential clinical applications. Through his expertise, Zhou has contributed to the development of advanced models like MaskSleepNet and the Lightweight Segmented Attention Network, which have furthered the understanding and efficiency of sleep staging processes.

Professional Profile

Education

Wei Zhou completed his undergraduate studies in Electronic Information Engineering at Sichuan University in 2019, where he gained foundational knowledge in electrical engineering and signal processing. He then pursued a Ph.D. in Biomedical Engineering at Fudan University, which he is expected to complete in 2024. During his doctoral studies, Zhou specialized in sleep stage scoring using advanced machine learning techniques, particularly focusing on the integration of multimodal signals, such as electroencephalography (EEG) and electrooculography (EOG), to improve the accuracy of sleep analysis models. His research is rooted in both biomedical engineering and artificial intelligence, fields in which he has developed deep expertise. Zhou’s academic journey at two prestigious universities in China provided him with a strong interdisciplinary foundation, combining engineering principles with biomedical research. This educational background has enabled him to develop and refine innovative methodologies, making significant contributions to the field of sleep science.

Professional Experience

Wei Zhou is currently a lecturer at Nanjing University of Information Science and Technology, where he is involved in both teaching and research. His professional experience focuses primarily on the application of artificial intelligence and machine learning in biomedical engineering, specifically in the field of sleep analysis. Zhou’s work involves designing and developing algorithms that integrate electroencephalography (EEG) and electrooculography (EOG) signals for improved sleep staging, addressing challenges such as missing data and device inconsistencies. His role as a lecturer also includes mentoring students, conducting academic research, and publishing in top-tier journals. Prior to his current position, Zhou gained hands-on experience through various academic projects during his doctoral studies at Fudan University, where he developed novel approaches to sleep staging and contributed to projects involving both theoretical research and real-world applications. Zhou’s career reflects his commitment to advancing the field of biomedical engineering through academic excellence and innovative research. His professional trajectory highlights his growth as a researcher and educator, as well as his dedication to solving complex health-related challenges using advanced technologies.

Research Interests

Wei Zhou’s primary research interest lies in the application of machine learning and artificial intelligence techniques to sleep analysis. Specifically, he focuses on improving the accuracy and reliability of sleep stage scoring systems by integrating multimodal data, such as electroencephalography (EEG) and electrooculography (EOG). His research addresses the challenges of heterogeneous signals and data noise, which are common in sleep studies. Zhou has developed advanced algorithms like the pseudo-siamese neural network, MaskSleepNet, and the Lightweight Segmented Attention Network, all aimed at enhancing sleep stage classification and handling issues like device inconsistency and missing data. His work also explores the use of hybrid systems and optimization algorithms to improve the performance of sleep analysis models. Additionally, Zhou’s research interests extend to the broader application of machine learning in biomedical engineering, where he seeks to use advanced algorithms to address a variety of health-related challenges. He is passionate about integrating cutting-edge technologies into biomedical research to enhance both academic understanding and clinical applications, particularly in the context of sleep disorders.

Research Skills

Wei Zhou possesses a wide range of research skills, particularly in the areas of machine learning, artificial intelligence, and biomedical engineering. His expertise includes developing advanced algorithms for sleep stage classification using multimodal data, particularly EEG and EOG signals. Zhou is skilled in employing techniques such as convolutional neural networks (CNNs), attention mechanisms, and pseudo-siamese networks to create robust models that handle heterogeneous data and noise. His work also involves optimization algorithms, including biogeography-based optimization, to enhance model performance, particularly in cases with small sample sizes or limited data. Zhou is proficient in designing and implementing complex systems for biomedical signal processing, demonstrating his ability to combine engineering principles with health-related research. Additionally, he has experience with various data analysis and modeling tools, which he uses to validate his models across multiple public datasets. Zhou’s ability to innovate and adapt machine learning techniques to the challenges of biomedical research makes him a skilled and versatile researcher. His work is characterized by methodological rigor and a strong focus on improving the practical applications of his findings in clinical settings.

Awards and Honors

While specific awards and honors were not listed in the provided information, Wei Zhou’s research contributions have been widely recognized in the field of biomedical engineering and machine learning. His publications in prestigious journals such as the IEEE Journal of Biomedical and Health Informatics and IEEE Transactions on Neural Systems and Rehabilitation Engineering demonstrate the high regard in which his work is held within the academic community. Zhou’s innovative algorithms, such as MaskSleepNet and the Lightweight Segmented Attention Network, have gained attention for their potential to improve sleep stage classification and address real-world challenges in sleep analysis. His ability to produce impactful research that addresses critical issues in sleep staging, such as device inconsistency and data noise, positions him as a leading figure in his field. Zhou’s ongoing contributions to both academic research and the development of practical technologies suggest that he will continue to receive recognition for his work in the future. His research has the potential to revolutionize sleep analysis and provide valuable insights into the diagnosis and treatment of sleep disorders.

Conclusion

Wei Zhou is undoubtedly a strong candidate for the Best Researcher Award due to his innovative contributions to sleep stage scoring, the development of advanced machine learning techniques, and the significant potential impact of his work. His research has made notable strides in solving long-standing challenges in the field of sleep analysis, especially in addressing heterogeneous data and improving the accuracy of automated sleep staging. However, expanding his research’s interdisciplinary reach, ensuring the scalability of his models, and incorporating longitudinal studies could further enhance his impact and demonstrate the real-world applicability of his work. His current contributions, however, make him a leader in the field, positioning him as a highly deserving nominee for the award.

Publication Top Notes

  1. Outlier Handling Strategy of Ensembled-Based Sequential Convolutional Neural Networks for Sleep Stage Classification
  2. PSEENet: A Pseudo-Siamese Neural Network Incorporating Electroencephalography and Electrooculography Characteristics for Heterogeneous Sleep Staging
    • Authors: Wei Zhou, Ning Shen, Ligang Zhou, Minghui Liu, Yiyuan Zhang, Cong Fu, Huan Yu, Feng Shu, Wei Chen, Chen Chen
    • Year: 2024
    • Journal: IEEE Journal of Biomedical and Health Informatics
    • DOI: 10.1109/JBHI.2024.3403878
  3. A Lightweight Segmented Attention Network for Sleep Staging by Fusing Local Characteristics and Adjacent Information
    • Authors: Wei Zhou, Hangyu Zhu, Ning Shen, Hongyu Chen, Cong Fu, Huan Yu, Feng Shu, Chen Chen, Wei Chen
    • Year: 2023
    • Journal: IEEE Transactions on Neural Systems and Rehabilitation Engineering
    • DOI: 10.1109/TNSRE.2022.3220372
  4. A Hybrid Expert System for Individualized Quantification of Electrical Status Epilepticus During Sleep Using Biogeography-Based Optimization
    • Authors: Wei Zhou, Xian Zhao, Xinhua Wang, Yuanfeng Zhou, Yalin Wang, Long Meng, Jiahao Fan, Ning Shen, Shuizhen Zhou, Wei Chen et al.
    • Year: 2022
    • Journal: IEEE Transactions on Neural Systems and Rehabilitation Engineering
    • DOI: 10.1109/TNSRE.2022.3186942
  5. An Energy Screening and Morphology Characterization-Based Hybrid Expert Scheme for Automatic Identification of Micro-Sleep Event K-Complex
    • Authors: Xian Zhao, Chen Chen, Wei Zhou, Yalin Wang, Jiahao Fan, Zeyu Wang, Saeed Akbarzadeh, Wei Chen
    • Year: 2021
    • Journal: Computer Methods and Programs in Biomedicine
    • DOI: 10.1016/j.cmpb.2021.105955

 

Rabia Toprak | Engineering | Best Researcher Award

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Assist. Prof. Dr. Rabia Toprak | Engineering | Best Researcher Award

Electrical-Electronics Engineering,  Karamanoglu Mehmetbey University,  Turkey

Rabia Toprak, an Assistant Professor at Karamanoglu Mehmetbey University, holds a Ph.D. in Electrical-Electronics Engineering from Konya Technical University, where her thesis focused on the detection of cancerous tissues using advanced antenna structures. With extensive research experience, she has participated in multiple national projects, including the development of high-gain microstrip antennas for medical applications and investigations into natural fiber-reinforced composites. Toprak has published numerous articles in international refereed journals, contributing to advancements in antenna design for cancer detection and electromagnetic field studies. Her teaching contributions span both undergraduate and graduate courses, where she emphasizes the principles of electromagnetics. Rabia Toprak’s dedication to innovative research and her significant impact on the fields of telecommunications and biomedical engineering make her a highly suitable candidate for the Research for Best Researcher Award, recognizing her contributions to academia and her commitment to improving health outcomes through technology.

Profile

Professional Experience

Rabia Toprak has built a solid academic career in the field of electrical-electronic engineering, specializing in telecommunications. She currently holds the position of Assistant Professor at Karamanoglu Mehmetbey University, having previously served as a research assistant in the same department from 2013 to 2023. Her long-standing affiliation with the academic community highlights her commitment to both teaching and research. Toprak’s experience includes leadership roles in various scientific projects, particularly those focusing on antenna designs for medical applications, further showcasing her expertise in applied electromagnetics.

Research Interests

Rabia Toprak’s research interests lie at the intersection of electrical engineering and biomedical applications, particularly in the design and implementation of microstrip antennas for medical diagnostics. Her doctoral work focused on the detection of cancerous tissues using high-gain microstrip and horn antenna structures, showcasing her commitment to advancing healthcare technologies. Toprak has contributed to various projects investigating the electrical properties of pathological tissues and has designed microstrip antennas for detecting cardiovascular conditions. Additionally, her work includes the development of natural fiber-reinforced epoxy/polymer-based hybrid composites for antenna applications, reflecting her interest in sustainable materials. With numerous publications in reputable journals, Toprak continues to explore innovative solutions for improving diagnostic methods in medicine, making significant contributions to both engineering and healthcare fields. Her ongoing projects include research on the effects of antenna designs on breast and colon tissue samples, further establishing her expertise in medical engineering.

Research Skills

Rabia Toprak has demonstrated exceptional research skills throughout her academic and professional career. As an Assistant Professor in the Department of Electrical-Electronic Engineering at Karamanoğlu Mehmetbey University, she has actively engaged in numerous research projects focused on innovative applications of microstrip antennas for medical diagnostics. Her expertise encompasses the design and implementation of antennas for detecting cancerous tissues and cardiovascular conditions, showcasing her proficiency in both theoretical and practical aspects of electromagnetic engineering. Toprak’s research is underpinned by her ability to conduct comprehensive literature reviews, design experimental setups, and analyze complex data. She has published multiple articles in esteemed international journals, reflecting her commitment to advancing knowledge in her field. Additionally, her involvement in collaborative research projects, such as the detection of cancer tissues and the design of hybrid composite substrates, highlights her strong teamwork and project management capabilities. Overall, Rabia Toprak’s research skills position her as a leading figure in her area of expertise.

Awards and Honors

Rabia Toprak, Assistant Professor at Karamanoglu Mehmetbey University, has garnered notable recognition for her innovative research in the field of electrical and electronic engineering. Her pivotal contributions include significant advancements in microstrip antenna technology, particularly in applications related to cancer detection and cardiovascular monitoring. In 2022, she received a prestigious grant from Higher Education Institutions for her project on the detection of cancerous tissues, highlighting her leadership in national research initiatives. Additionally, her work has been featured in several high-impact international journals, showcasing her commitment to advancing scientific knowledge. Toprak’s presentations at various international conferences have further solidified her reputation as a leading researcher in her field. Her dedication to education is evident in her teaching roles, where she inspires the next generation of engineers. These accolades reflect her exceptional contributions to both academia and the scientific community, establishing her as a prominent figure in engineering research.

Conclusion 

Rabia Toprak is a strong candidate for the Research for Best Researcher Award due to her significant contributions to the field of electrical and electronic engineering, particularly in medical applications. With a doctoral thesis focusing on the detection of cancerous tissues using advanced microstrip and horn antenna structures, she has demonstrated a commitment to innovative research with practical implications. Her role in various national scientific projects, such as the investigation of electrical properties of pathological tissues and the development of natural fiber-reinforced hybrid composites, underscores her multidisciplinary approach and collaboration within the scientific community. Furthermore, her numerous publications in reputable international journals highlight her ongoing dedication to advancing knowledge in her field. Rabia’s expertise, research impact, and teaching contributions at Karamanoglu Mehmetbey University reflect her commitment to excellence and innovation in research, making her an ideal candidate for this prestigious award.

Publication Top Notes

  • An approach to determine pathological breast tissue samples with free-space measurement method at 24 GHz
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Ahmet Kayabasi, Zeliha Esin Celik, Fatma Hicret Tekin, Dilek Uzer
    • Year: 2024
    • Citations: 0 (as it is a recent publication)
  • Comparison of Far Field and Near Field Values of Skin Tissue Measured Using Microstrip Antenna Structure
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2022
    • Citations: 1
  • Investigation of Gain Enhancement in Microstrip Antenna Structure in Pathological Tissue Samples
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2021
    • Citations: 2
  • Patolojik Doku Örneklerinde Mikroşerit Anten Yapısında S-Parametrelerine Ait Normalizasyon Değerlerinin İncelenmesi
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2021
    • Citations: 0 (as it is a recent publication)
  • Determination of Cardiovascular Occlusion with Microstrip Antennas
    • Authors: H. Uyanik, D. Uzer, Rabia Toprak, Seyfettin Sinan Gultekin
    • Year: 2020
    • Citations: 3
  • Kanser Hastalığı Tespitine Yönelik ISM Bandında Çalışan Mikroşerit Yama Yapılı İki Antenin Elektromanyetik Alan ve Saçılma Parametreleri Verilerinin Değerlendirilmesi ve Kıyaslanması
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2020
    • Citations: 0 (as it is a recent publication)
  • Microstrip antenna design with circular patch for skin cancer detection
    • Authors: Rabia Toprak, Y. Ünlü, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2019
    • Citations: 5
  • Modeling congestion of vessel on rectangular microstrip antenna and evaluating electromagnetic signals
    • Authors: Rabia Toprak, Seyfettin Sinan Gultekin, Dilek Uzer
    • Year: 2017
    • Citations: 0 (as it is a recent publication)
  • A Microstrip Patch Antenna Design for Breast Cancer Detection
    • Authors: Rabia Caliskan, Seyfettin Sinan Gultekin, Dilek Uzer, Ozgur Dundar
    • Year: 2015
    • Citations: 7

Miqin Zhang | Engineering | Best Researcher Award

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Prof. Miqin Zhang | Engineering | Best Researcher Award

Dept of materials science and engineering, UNIVERSITY OF WASHINGTON,  United States

Miqin Zhang is a distinguished candidate for the Best Researcher Award, holding the Kyocera Chair Professorship in Materials Science and Engineering at the University of Washington and serving as a professor in various medical departments. His academic journey includes a Ph.D. from UC Berkeley, laying a solid foundation in materials science and biomedical engineering. Zhang’s research focuses on nanoscience and its applications in cancer therapy, tissue engineering, and biosensing, resulting in over 200 publications and more than 43,000 citations. His innovative work, especially in biodegradable hydrogels and targeted drug delivery systems, has significantly advanced therapeutic strategies. Recognition as a Highly Cited Researcher and fellowships from esteemed organizations highlight his influence in the field. Miqin Zhang’s multidisciplinary expertise and substantial contributions to science make him a deserving recipient of the Best Researcher Award, inspiring future researchers to strive for excellence and innovation in their work.

 

Profile:

Education

Miqin Zhang has an impressive educational background that lays the foundation for his distinguished career in materials science and engineering. He earned his Ph.D. in Materials Science and Engineering with a minor in Biomedical Engineering from the University of California, Berkeley, in 1999. Prior to this, he completed his Master of Science in Mechanical Engineering at the University of Victoria in Canada in 1993. His academic journey began at Jiangxi University of Science and Technology in China, where he obtained his Bachelor of Science in Metallurgical and Chemical Engineering in 1983. This rigorous training, coupled with research experience as a graduate assistant, equipped Zhang with a robust understanding of materials science principles and their applications in biomedical contexts. His extensive educational background not only demonstrates his commitment to academic excellence but also provides the expertise necessary for his impactful research in nanotechnology and regenerative medicine.

 

Professional Experiences 

Miqin Zhang has an extensive professional background in the field of materials science and engineering, currently serving as a Professor in the Department of Materials Science & Engineering at the University of Washington since 1999. His academic journey includes roles as an Associate Professor and Assistant Professor within the same department, highlighting a progressive career dedicated to research and education. Prior to his tenure at the University of Washington, Zhang gained valuable experience as a Graduate Research Assistant at both the University of California, Berkeley, and the University of Victoria, Canada. His early career began in China, where he worked as a Research Assistant and Associate at the Zhejiang Research Institute of Metallurgy, contributing to significant advancements in metallurgical research. This diverse and rich professional experience underscores his expertise in materials science and engineering, positioning him as a prominent figure in interdisciplinary research and collaboration.

 

Research skills 

Miqin Zhang exhibits exceptional research skills in the fields of nanoscience, biomaterials, and tissue engineering. His expertise encompasses the development of innovative nanomaterials for targeted drug delivery, particularly in cancer therapy, showcasing his proficiency in integrating engineering principles with biomedical applications. Zhang’s analytical skills are evident in his ability to conduct complex experimental designs, including the use of biodegradable hydrogels for stem cell delivery and tissue regeneration. His extensive publication record, which includes over 200 peer-reviewed articles with high citation rates, demonstrates not only his capacity for impactful research but also his commitment to advancing scientific knowledge. Furthermore, his leadership roles in collaborative projects, coupled with his engagement in interdisciplinary research, reflect his adeptness at fostering teamwork and driving innovation within diverse research environments.

 

Award And Recoginition 

Miqin Zhang is a distinguished candidate for the Best Researcher Award, holding the Kyocera Chair Professorship in the Department of Materials Science and Engineering at the University of Washington. His academic journey includes a Ph.D. in Materials Science and Engineering, complemented by extensive research experience in nanotechnology and its applications in cancer therapy, tissue engineering, and biosensing. With over 200 peer-reviewed publications and more than 43,000 citations, his work significantly impacts the scientific community. Zhang has received numerous accolades, including fellowships in prestigious organizations like The Royal Society of Chemistry and recognition as a Highly Cited Researcher. His innovative research, particularly in developing biodegradable hydrogels and nanomaterials, has revolutionized therapeutic approaches. By awarding him this honor, we not only recognize his exceptional contributions but also inspire future generations to pursue excellence in research and innovation within the fields of materials science and biomedical engineering.

 

Conclusion

 Miqin Zhang exemplifies the ideal candidate for the Best Researcher Award due to his exceptional contributions to the fields of materials science and engineering, particularly in nanotechnology and biomedical applications. His extensive academic and professional background, highlighted by his current positions at the University of Washington, reflects his commitment to interdisciplinary research and innovation. With over 200 peer-reviewed publications and more than 43,000 citations, Zhang’s work has significantly advanced therapeutic strategies for cancer treatment and tissue engineering. His numerous accolades, including fellowships and recognition as a Highly Cited Researcher, further underscore his influence and leadership in the scientific community. Awarding Zhang this recognition would honor his remarkable achievements and inspire future researchers to pursue excellence and innovation, ultimately contributing to the advancement of science and improved health outcomes. His dedication and impact make him a deserving recipient of this prestigious award.

Publication Top Notes

  • Green synthesis of iron-doped graphene quantum dots: an efficient nanozyme for glucose sensing
    Authors: Xinqi Li, Guanyou Lin, Lijun Zhou, Octavia Prosser, Mohammad H. Malakooti, Miqin Zhang
    Year: 2024
    Citation: DOI: 10.1039/D4NH00024B
  • Injectable Biodegradable Chitosan–PEG/PEG–Dialdehyde Hydrogel for Stem Cell Delivery and Cartilage Regeneration
    Authors: Xiaojie Lin, Ruofan Liu, Jacob Beitzel, Yang Zhou, Chloe Lagadon, Miqin Zhang
    Year: 2024
    Citation: DOI: 10.3390/gels10080508
  • Human Neural Stem Cell Expansion in Natural Polymer Scaffolds Under Chemically Defined Condition
    Authors: Fei‐Chien Chang, Matthew Michael James, Yang Zhou, Yoshiki Ando, Hadi M. Zareie, Jihui Yang, Miqin Zhang
    Year: 2024
    Citation: DOI: 10.1002/adbi.202400224
  • A Chitosan Scaffold Supports the Enhanced and Prolonged Differentiation of HiPSCs into Nucleus Pulposus-like Cells
    Authors: Yuanzhang Tang, Yang Zhou, Miqin Zhang
    Year: 2024
    Citation: DOI: 10.1021/acsami.4c06013
  • Advances in nanoparticle-based mRNA delivery for liver cancer and liver-associated infectious diseases
    Authors: Seokhwan Chung, Chan Mi Lee, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1039/D2NH00289B
  • 3D chitosan scaffolds support expansion of human neural stem cells in chemically defined condition
    Authors: Fei-Chien Chang, Matthew Michael James, Abdullah Mohammed Qassab, Yang Zhou, Yoshiki Ando, Min Shi, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1016/j.matt.2023.08.014
  • Chitosan Scaffolds as Microcarriers for Dynamic Culture of Human Neural Stem Cells
    Authors: Yoshiki Ando, Fei-Chien Chang, Matthew James, Yang Zhou, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.3390/pharmaceutics15071957
  • Iron Oxide Nanoparticle-Mediated mRNA Delivery to Hard-to-Transfect Cancer Cells
    Authors: Jianxi Huang, Guanyou Lin, Taylor Juenke, Seokhwan Chung, Nicholas Lai, Tianxin Zhang, Tianyi Zhang, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.3390/pharmaceutics15071946
  • Enhanced Cell Penetration and Pluripotency Maintenance of hiPSCs in 3D Natural Chitosan Scaffolds
    Authors: Yuanzhang Tang, Yang Zhou, Guanyou Lin, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1002/mabi.202200460
  • Ligand Chemistry in Antitumor Theranostic Nanoparticles
    Authors: Guanyou Lin, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1021/acs.accounts.3c00151
  • 3D Porous Scaffold-Based High-Throughput Platform for Cancer Drug Screening
    Authors: Yang Zhou, Gillian Pereira, Yuanzhang Tang, Matthew James, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.3390/pharmaceutics15061691
  • Data from Time-Resolved MRI Assessment of Convection-Enhanced Delivery by Targeted and Nontargeted Nanoparticles in a Human Glioblastoma Mouse Model
    Authors: Zachary R. Stephen, Peter A. Chiarelli, Richard A. Revia, Kui Wang, Forrest Kievit, Chris Dayringer, Mike Jeon, Richard Ellenbogen, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1158/0008-5472.c.6511271
  • Iron Oxide Nanoparticles Decorated with Functional Peptides for a Targeted siRNA Delivery to Glioma Cells
    Authors: Seokhwan Chung, Yutaro Sugimoto, Jianxi Huang, Miqin Zhang
    Year: 2023
    Citation: DOI: 10.1021/acsami.2c17802
  • Electrospun nanofibers for 3-D cancer models, diagnostics, and therapy
    Authors: Ariane Erickson, Peter A. Chiarelli, Jianxi Huang, Sheeny Lan Levengood, Miqin Zhang
    Year: 2022
    Citation: DOI: 10.1039/D2NH00328G
  • High-Throughput Dispensing of Viscous Solutions for Biomedical Applications
    Authors: Richard A. Revia, Brandon Wagner, Matthew James, Miqin Zhang
    Year: 2022
    Citation: DOI: 10.3390/mi13101730
  • Enzymatic and Cellular Degradation of Carbon-Based Biconcave Nanodisks
    Authors: Zhiyong Wei, Qingxin Mu, Hui Wang, Guanyou Lin, Miqin Zhang
    Year: 2022
    Citation: DOI: 10.3390/mi13071144
  • Iron oxide nanoparticle-mediated radiation delivery for glioblastoma treatment
    Authors: Peter A. Chiarelli, Richard A. Revia, Zachary R. Stephen, Kui Wang, Forrest M. Kievit, Jordan Sandhu, Meenakshi Upreti, Seokhwan Chung, Richard G. Ellenbogen, Miqin Zhang
    Year: 2022
    Citation: DOI: 10.1016/j.mattod.2022.04.001