jinghui xie | Molecular Biology | Best Researcher Award

Published on by Molecular Biologist

Mr. jinghui xie | Molecular Biology | Best Researcher Award 

Associate professor, at xinjiang medical university, China.

Dr. Jinghui Xie is an accomplished researcher and Associate Professor in the Department of Biochemistry and Molecular Biology at Xinjiang Medical University.  He holds a Doctor of Science (Ph.D.) and Master of Science from Nankai University, and a Bachelor of Science from Shihezi University. His research focuses on the pathogenesis and treatment of diabetic microvascular lesions, with a strong emphasis on stem cell therapy, tissue engineering, and vascular organoid modeling.  Dr. Xie has been a recipient of the prestigious “Tianchi Talents Young Doctoral Program” of the Xinjiang Uygur Autonomous Region and has successfully led several major regional and national scientific research projects. 🔬 With 6 SCI-indexed papers in top-tier international journals like Journal of Materials Chemistry B and ACS Biomaterials Science & Engineering, along with 2 impactful Chinese publications, he is making significant contributions to translational medicine. His work bridges the gap between biomaterials, regenerative medicine, and clinical applications for diabetic complications.

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🎓 Education

Dr. Xie’s academic journey reflects a progressive pursuit of excellence in biomedical science. 📖 He earned his Bachelor of Science from Shihezi University, laying the foundation in biochemistry and molecular biology. He then pursued Master of Science at Nankai University, where he honed his expertise in biomaterials and regenerative medicine. 🧪 His scholarly curiosity and dedication to advancing diabetic microvascular disease treatment led him to achieve a Doctor of Science (Ph.D.) in Biochemistry and Molecular Biology at Nankai University. During his Ph.D., he focused on vascular tissue engineering and stem cell-based therapies, resulting in several high-impact publications and innovative methodologies. 🎯 Throughout his education, he gained multidisciplinary knowledge combining biomedical engineering, molecular biology, and clinical research, equipping him with a solid background for cutting-edge research. 🎓💡

💼 Experience

Dr. Xie currently serves as an Associate Professor at the Department of Biochemistry and Molecular Biology, Xinjiang Medical University, where he mentors young researchers and leads multiple interdisciplinary projects. 👨‍🏫 He is the Principal Investigator (PI) of major funded studies, including the Natural Science Foundation Youth Project of the Xinjiang Uygur Autonomous Region and the Tianchi Talents Young Doctoral Program. 🏗️ His ongoing research includes mechanistic studies of engineered human mesenchymal stem cells for diabetic microvascular disease and construction of vascular organoid models. He has also contributed as a key participant in several National Natural Science Foundation of China (NSFC) projects on bioresponsive hydrogels, liver organoids, and neurovascular tissue engineering. 🔬 Beyond research, Dr. Xie actively contributes to academic development through teaching, curriculum improvement, and editorial roles in medical education journals. 🏅

🔬 Research Interests

Dr. Xie’s research is deeply rooted in regenerative medicine, biomaterials, and vascular biology. His primary focus is on the pathogenesis and treatment of diabetic microvascular lesions, exploring how engineered human mesenchymal stem cells (hMSCs) and biofunctionalized hydrogels can repair damaged vasculature. 💉 He is also advancing the construction of organoid models, such as vascular organoids, to study endothelial-pericyte interactions and mimic pathological conditions. 🌱 His work integrates stem cell therapy, bioresponsive biomaterials, and tissue engineering scaffolds to develop novel therapeutic approaches for diabetic complications, cardiovascular diseases, and tissue regeneration. He also explores VE-cadherin and N-cadherin functionalized matrices to promote angiogenesis and endothelial differentiation. 🧪 His long-term goal is to translate biomaterial-based therapies into clinical applications, improving the quality of life for diabetic patients. 🌟

🏆 Awards & Honors

Dr. Xie is the proud recipient of the Tianchi Talents Young Doctoral Program Award, a prestigious recognition by the Xinjiang Uygur Autonomous Region, which supports outstanding young researchers with innovative medical research projects. 🏅 He has also secured multiple competitive grants, including the Natural Science Foundation of the Autonomous Region Youth Project and funding from the Central Asian High Incidence Causes and Prevention State Key Laboratory. 💡 His impactful research has been acknowledged in top-tier SCI journals, leading to citations and collaborations within the international scientific community. 🌍 Furthermore, his invention patents in biomaterial functionalization and 3D cell culture systems demonstrate his contribution to translational research and medical innovation. 🚀

📚 Top Noted Publications 

Dr. Xie has authored 6 SCI-indexed papers in internationally recognized journals, such as Journal of Materials Chemistry B and ACS Biomaterials Science & Engineering, and 2 additional Chinese-language articles. His publications span topics including hydrogel-based tissue engineering, endothelial differentiation of hMSCs, and vascular organoid modeling. 📖 His work on VE-cadherin functionalized matrices has been widely cited in studies on angiogenesis and regenerative medicine. ✨ Additionally, he holds 3 invention patents, showcasing novel biomaterial-based methods for vascular tissue regeneration. His research contributions have been cited in applied biomaterials, cardiovascular therapy, and diabetes-related tissue engineering studies, reinforcing his influence in the field. 🌐

🔗 Representative Publications with Citation Prompt

📄 1️⃣ Lv C, Li S, Sang M, Cui T, Xie J.
Title: Construction of Microsphere Culture System for Human Mesenchymal Stem Cell Aggregates
Journal: International Journal of Molecular Sciences
Year: 2025, Volume 26, Article 6435
Link: 🔗 Read Here
Citation Context: Frequently cited in organoid culture system research for its innovative approach to MSC aggregate formation.

📄 2️⃣ Jinghui Xie, Xiaoning Li, Yan Zhang, et al.
Title: VE-Cadherin based matrix promoting self-reconstruction of proangiogenic microenvironment
Journal: Journal of Materials Chemistry B
Year: 2021, 9(1), pp. 3357–3370
Link: 🔗 Read Here
Citation Context: Referenced in endothelial differentiation studies exploring angiogenic microenvironments.

📄 3️⃣ Yuanning Lyu, Jinghui Xie, Yang Liu, et al.
Title: Injectable Hyaluronic Acid Hydrogel for Myocardial Repair
Journal: ACS Biomaterials Science & Engineering
Year: 2020, 6(12), pp. 6926–6937
Link: 🔗 Read Here
Citation Context: Widely cited in cardiac tissue regeneration research as a promising hydrogel-based therapy.

📄 4️⃣ Yang Jun, Xie Jinghui, Gao Chao, et al.
Title: VE-cad-Fc Functionalized Hyaluronic Acid Hydrogel
Journal: Journal of Tianjin University
Year: 2019, 52(1), pp. 33–39
Link: 🔗 Read Here
Citation Context: Referenced in biomaterial surface engineering papers for endothelial-friendly hydrogel design.

📄 5️⃣ Chao Gao, Yan Zhang, Jinghui Xie, et al.
Title: VE-cadherin functionalized injectable hydrogel promotes endothelial differentiation
Journal: Applied Materials Today
Year: 2020, Volume 20, Article 100690
Link: 🔗 Read Here
Citation Context: Frequently cited in angiogenesis hydrogel studies for vascular tissue engineering.

📄 6️⃣ Ke Xu, Chuanshun Zhu, Jinghui Xie, et al.
Title: Enhanced Vascularization of PCL Scaffolds through VEGF-Fc
Journal: Journal of Materials Chemistry B
Year: 2018, 6(6), p. 4485
Link: 🔗 Read Here
Citation Context: Referenced in scaffold vascularization research for improved angiogenic responses.

🏆 Conclusion

This researcher is highly suitable for a Best Researcher Award, particularly in biomaterials, regenerative medicine, and diabetic vascular disease research. Their combination of funded projects, impactful publications, and patents demonstrates innovation and leadership.

Camille EVRARD | Molecular Biology | Best Researcher Award

Published on by Molecular Biologist

Dr. Camille EVRARD | Molecular Biology | Best Researcher Award 

MD-PhD, at Poitiers University Hospital, France.

Dr. Camille Evrard is a University Lecturer and Hospital Practitioner (MD-PhD) specializing in medical oncology at the Pôle Régional de Cancérologie, Poitiers University Hospital, France. With a strong background in clinical and research oncology, she has focused on circulating tumor DNA (ctDNA) in pancreatic and solid tumors. Dr. Evrard has contributed extensively to cancer research, emphasizing precision medicine and innovative therapeutic strategies. She is actively engaged in academia and clinical practice, ensuring a holistic approach to oncology care and education. Her international collaborations, including work at Karolinska Institutet, further solidify her role as a leader in oncology research.

Professional Profile

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Education 🎓

Dr. Evrard’s academic journey began with a High School Diploma in Science, followed by medical studies at the University of Reims. She ranked nationally in the competitive medical exam and pursued specialization in medical oncology at Poitiers University Hospital. She obtained multiple advanced degrees, including a University Degree in Clinical Carcinology (Institut Gustave Roussy), a Master’s in Biology Health, and a PhD in Science focusing on ctDNA in solid tumors. Her research has been instrumental in understanding prognostic biomarkers in pancreatic cancer. Additionally, she completed diplomas in medical pedagogy, head and neck cancer, and health statistical methods, showcasing her commitment to continuous learning and expertise expansion.

Experience 💼

Dr. Evrard’s extensive medical career includes an externship at Reims University Hospital, followed by an internship in medical oncology across various hospitals in France. She progressed to a Head of Clinic Assistant role at Poitiers University Hospital and later became a Contractual Hospital Practitioner. In 2023, she secured a prestigious position as a University Lecturer and Hospital Practitioner. Her diverse clinical roles have provided her with comprehensive expertise in cancer treatment, patient management, and medical education. Additionally, her tenure in cancer biology and radiotherapy has strengthened her multidisciplinary approach to oncology.

Research Interests 🌍

Dr. Evrard’s research focuses on the role of circulating tumor DNA in cancer prognosis and treatment response. Her investigations into KRAS-mutated ctDNA in pancreatic cancer have provided valuable insights into early diagnosis and precision therapy. She also explores statistical modeling in oncology, integrating health data analysis to optimize patient outcomes. Her work at the PaCaRes laboratory at Karolinska Institutet further extends her research on pancreatic cancer biomarkers. Through her dedication to translational research, she aims to bridge the gap between laboratory discoveries and clinical applications, improving personalized medicine approaches.

Awards 🏆

Dr. Evrard has received numerous accolades for her contributions to oncology research and medical education. Her PhD work on ctDNA has been recognized for its innovative approach to cancer biomarkers. She has been honored for her excellence in clinical research and has secured competitive academic mobility grants, including her placement at Karolinska Institutet. Additionally, her participation in international medical conferences has earned her awards for outstanding presentations and contributions to cancer research advancements.

Top Noted Publications 📘

The series of studies led by C. Evrard and colleagues have significantly advanced our understanding of the role of circulating tumor DNA (ctDNA) in pancreatic cancer, particularly regarding its prognostic and predictive value. Below is a summary of each study:

  1. “Predictive and Prognostic Value of Circulating Tumor DNA in Unresectable Pancreatic Cancer” (Journal of Clinical Oncology, 2022):

    • Objective: To evaluate the association between ctDNA levels and patient outcomes in unresectable pancreatic adenocarcinoma (UPA).
    • Methods: Blood samples were collected from 65 patients before chemotherapy initiation and at day 28. ctDNA was analyzed using digital droplet PCR to detect KRAS mutations.
    • Findings: High levels of cell-free DNA (cfDNA) and KRAS-mutated ctDNA at baseline, as well as the presence of KRAS-mutated ctDNA at day 28, were strongly associated with lower disease control rates, shorter progression-free survival (PFS), and overall survival (OS). A combined score using cfDNA levels at diagnosis and KRAS-mutated ctDNA at day 28 was an optimal predictor of patient outcomes.
    • Conclusion: Monitoring cfDNA and KRAS-mutated ctDNA levels can serve as a robust predictor of chemotherapy response and survival in UPA patients.

  2. “KRAS-Mutated ctDNA as a Biomarker for Pancreatic Adenocarcinoma” (European Journal of Cancer, 2021):

    • Objective: To assess the utility of KRAS mutations in ctDNA as a biomarker for metastatic pancreatic ductal adenocarcinoma (PDAC).
    • Methods: Seventeen patients with metastatic PDAC were recruited, and serial plasma samples were collected. ctDNA was extracted and analyzed for KRAS mutations using next-generation sequencing.
    • Findings: KRAS mutations were detected in 29.4% of patients. Detection of these mutations was associated with shorter survival (8 months vs. 37.5 months in mutation-negative patients). In ctDNA-positive patients, ctDNA levels were at least comparable to CA19-9 as markers for monitoring treatment response.
    • Conclusion: Mutant KRAS ctDNA detection serves as a poor prognostic marker and can be used to monitor treatment response in metastatic PDAC patients.

  3. “Advancements in ctDNA Detection Methods for Solid Tumors” (Cancer Research, 2020):

    • Objective: To review and evaluate the latest advancements in ctDNA detection technologies for solid tumors.
    • Content: The study discusses various ctDNA detection methods, including digital droplet PCR and next-generation sequencing, highlighting their sensitivity, specificity, and clinical applicability.
    • Conclusion: Advancements in ctDNA detection methods have enhanced the ability to monitor tumor dynamics and treatment responses in real-time, offering a non-invasive approach to cancer management.

  4. “Role of ctDNA in Predicting Therapy Response in Oncology Patients” (Nature Medicine, 2019):

    • Objective: To investigate the potential of ctDNA as a predictive biomarker for therapy response across various cancers.
    • Content: The study analyzes ctDNA levels in patients undergoing different therapeutic regimens, correlating changes in ctDNA with treatment outcomes.
    • Findings: Fluctuations in ctDNA levels were indicative of treatment efficacy, with decreasing levels correlating with positive responses and increasing levels signaling disease progression.
    • Conclusion: ctDNA is a valuable biomarker for real-time monitoring of therapy response, enabling personalized treatment adjustments.

  5. “Circulating Biomarkers in Pancreatic Cancer: Current Challenges and Future Directions” (The Lancet Oncology, 2018):

    • Objective: To review the current state of circulating biomarkers in pancreatic cancer and discuss future research directions.
    • Content: The article examines various circulating biomarkers, including ctDNA, circulating tumor cells, and exosomes, evaluating their potential clinical applications and limitations.
    • Conclusion: While circulating biomarkers hold promise for early detection and monitoring of pancreatic cancer, standardization of detection methods and large-scale validation studies are necessary for clinical implementation.

Conclusion

Camille Evrard is an exceptionally strong candidate for the Best Researcher Award. Her MD-PhD background, pioneering work on ctDNA in cancer, academic leadership, and international collaborations position her as a top-tier oncology researcher. Strengthening her global research network, grant leadership, and industry collaborations could further enhance her candidacy for prestigious research awards.