Titus Luomba Ombori | Analytical Techniques | Best Researcher Award

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Dr. Titus Luomba Ombori | Analytical Techniques
| Best Researcher Award

Dr. Titus Luomba Ombori | University of Dar es Salaam, Mkwawa University College of Education | Tanzania

Dr. Titus Luomba Ombori, PhD, is a Tanzanian Geoarchaeologist and Senior Lecturer in Archaeological Science at the University of Dar es Salaam, Mkwawa University College of Education (MUCE),he has established a distinguished academic and research career with expertise in geoarchaeology, quaternary science, and cultural heritage management. He earned his PhD through the International Doctorate in Quaternary Science and Prehistory at the University of Ferrara, Italy, and previously obtained his MA and BA in Archaeology from the University of Dar es Salaam. His academic excellence is recognized by numerous awards, including the Erasmus Mundus PhD Scholarship, Sida/SAREC Fellowship, and government sponsorships. Dr. Ombori has broad professional memberships in prestigious organizations such as INQUA, SAfA, AFQUA, and EGU, reflecting his active participation in global scholarly communities. With extensive fieldwork experience across Tanzania and Italy, he has led and contributed to major archaeological and paleoenvironmental projects, including the Olduvai Gorge excavations, the DeepCHALLA drilling project, and the Mbuamaji site investigations. His research and consultancy work with UNESCO highlight his ability to bridge science, policy, and community impact. An accomplished scholar with influential publications and invited presentations worldwide, Dr. Ombori continues to shape archaeological knowledge and heritage conservation in Africa and beyond.

Profile: ORCID

Featured Publication

  • Ombori, T. L., Pirrie, D., Power, M. R., Skilling, I., Gidna, A. O., Mabulla, A. Z. P., Bushozi, P. M., Prendergast, M. E., & Grillo, K. M. (2025). Automated SEM-EDS mineralogical characterisation of archaeological pottery from Luxmanda and Mumba Rockshelter, Tanzania. Journal of Archaeological Science: Reports, 105, 105369.

 

Bei Li | Spectroscopy Analysis | Best Researcher Award

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Prof. Bei Li | Spectroscopy Analysis
| Best Researcher Award

Prof. Bei Li | University of Chinese Academy of Sciences | China

Prof. Bei Li is a distinguished Research Scientist at the Changchun Institute of Optics, Fine Mechanics and Physics, Chinese Academy of Sciences, and Chairman of Hooke Instruments Ltd. He has made pioneering contributions in spectroscopy, biophotonics, nonlinear optics, holography, and AI-based image processing. As Chief Scientist of national research programs and a recipient of prestigious honors including the National High-level Overseas Talent Award and the Jilin Provincial Outstanding Contribution Award, Prof. Li has demonstrated exceptional leadership in advancing optical science and its biomedical applications. He has successfully led six national-level and fourteen provincial-level projects, in addition to numerous municipal and industry collaborations, bridging fundamental science with practical innovation. His outstanding publication record includes 69 SCI-indexed papers, with citation metrics of 824 citations (h-index 17, i10-index 26, Google Scholar) and 516 citations from 427 documents with an h-index of 12 (Scopus). He also holds 27 granted patents and 14 new applications under review. Notably, his development of a microwell-assembled aluminum platform revolutionized single-cell Raman spectroscopy, enabling highly accurate cancer cell classification through machine learning integration. With deep collaborations spanning Cardiff University and Peking University, Prof. Li has advanced cross-disciplinary innovations of global significance, making him a strong candidate for the Best Researcher Award.

Profile: Google Scholar  |  Scopus

Featured Publications

  • Li, B (2026). Deep learning-assisted Raman spectroscopy for rapid lactic acid bacteria identification at the colony level. Spectrochimica Acta Part A: Molecular and Biomolecular Spectroscopy. Advance online publication.

  • Li, B. (2025). Metabolic activity profiling of high-temperature Daqu microbiota using single-cell Raman spectroscopy and deuterium isotope probing. Analytical Chemistry. Advance online publication.

  • Li, B.,(2025). High-viability circulating tumor cells sorting from whole blood at single cell level using laser-induced forward transfer-assisted microfiltration. Advanced Science. Advance online publication.

  • Li, B., (2025). High-throughput compact Raman spectrometer based on polarization transformation: Development and biological trials. Optics and Lasers in Engineering. Advance online publication.

 

 

 

Larissa MagalhĂŁes de Almeida Melo | Analytical Chemistry | Women Researcher Award

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Dr. Larissa MagalhĂŁes de Almeida Melo | Analytical Chemistry | Women Researcher Award

Pos doctor at Federal University of the Jequitinhonha and Mucuri Valleys | Brazil

Larissa MagalhĂŁes de Almeida Melo is a Brazilian researcher specializing in analytical and forensic chemistry, with an emphasis on electrochemical detection methods for drugs of abuse. She is currently pursuing her Ph.D. at the Federal University of the Jequitinhonha and Mucuri Valleys (UFVJM) under Prof. Dr. Wallans Torres Pio dos Santos. Her doctoral research focuses on developing portable, field-deployable methods for drug screening. In 2024, she undertook a Sandwich Ph.D. program at Manchester Metropolitan University with Prof. Craig Banks, further advancing her work in colorimetric and electrochemical sensors. With over 160 citations and an H-index of 9, Larissa has contributed significantly to high-impact journals in analytical chemistry. She combines her expertise in electrochemical sensing, device fabrication, and forensic toxicology to innovate rapid and cost-effective screening technologies. Her international collaborations and technical contributions highlight her growing influence in modern forensic science and public health monitoring.

Professional Profile

Google Scholar

Orcid

Education 

Larissa Melo’s academic journey demonstrates a progressive dedication to chemistry and engineering. She is currently a Ph.D. fellow (2021–2025) at UFVJM in Brazil, where her research involves the development of portable methods for forensic drug detection. In 2024, she participated in a Sandwich Ph.D. at Manchester Metropolitan University under Prof. Craig Banks. Prior to her doctorate, she earned a Master’s degree in Analytical Chemistry (2019–2021) from UFVJM, where she developed a screening method for synthetic tryptamines. She also completed a Bachelor’s in Chemical Engineering (2018–2023) and another in Science and Technology (2014–2018) at UFVJM. Her foundational education includes a technical course in Electrical Technology (2010–2013) from the Federal Institute of EspĂ­rito Santo. This solid multidisciplinary background has equipped her with strong skills in analytical instrumentation, electrochemistry, materials science, and chemical engineering, all of which support her advanced research in forensic applications.

Professional Experience 

Larissa Melo brings strong academic and research experience, particularly in forensic electrochemistry. Her doctoral work (2021–2025) at UFVJM focuses on creating portable devices for the electrochemical detection of synthetic drugs. In 2024, she joined Manchester Metropolitan University under a Sandwich Ph.D. program, working with Prof. Craig Banks on hybrid sensor systems. During her Master’s (2019–2021), she developed a fast electrochemical method for tryptamine detection. She has co-authored over 20 peer-reviewed publications in top journals, often collaborating with multidisciplinary teams on drug screening innovations using screen-printed electrodes, colorimetric methods, and 3D-printed analytical tools. Larissa has also contributed to critical reviews and sensor fabrication methods. Her experience includes technical work with disposable electrodes, boron-doped diamond sensors, and voltammetry. Additionally, she’s actively involved in developing environmentally friendly, field-portable diagnostic tools. Larissa’s practical and collaborative work underscores her capability in applying chemistry to real-world forensic and public health challenges.

Awards and Honors 

While specific awards are not explicitly listed, Larissa Melo’s research impact and international engagements reflect significant academic recognition. She was competitively selected for a Sandwich Ph.D. fellowship at Manchester Metropolitan University (2024), a testament to her research excellence and international collaboration skills. Her publication record includes articles in top-tier journals such as Electrochimica Acta, Talanta, TrAC, and Sensors and Actuators B: Chemical, often as the first or lead author. She has amassed over 165 citations and holds an H-index of 9, highlighting her work’s influence in analytical and forensic chemistry. Larissa’s interdisciplinary research on electrochemical and colorimetric methods for drug detection showcases her contribution to forensic science innovation. Her rapid rise as a productive early-career researcher, mentorship by globally recognized experts like Prof. Wallans dos Santos and Prof. Craig Banks, and verified academic credentials on the Lattes platform further confirm her growing stature in scientific communities.

Research Interests 

Larissa Melo’s research interests center around analytical chemistry, electrochemical sensing, and forensic science. Her work focuses on the development of rapid, portable, and cost-effective electrochemical and colorimetric detection methods for drugs of abuse. She is particularly interested in screen-printed electrodes, boron-doped diamond sensors, and 3D-printed electrochemical cells to detect substances such as synthetic cathinones, cannabinoids, tryptamines, amphetamines, and hallucinogens. Her interdisciplinary approach combines chemical engineering principles, material science, and electroanalysis to improve point-of-care diagnostics. Larissa also explores hybrid detection platforms combining colorimetric and electrochemical signals, enhancing sensitivity and specificity for field-based forensic analysis. She contributes to critical reviews and technical innovations in clinical toxicology, pharmaceutical analysis, and biosensors. Her goal is to make analytical methods more accessible, environmentally friendly, and applicable in real-time settings, such as customs, crime scenes, and emergency rooms.

Publication Top Notes

  1. Portable analytical methods for detecting synthetic cannabinoid receptor agonists: a critical review

  2. A dual colorimetric-electrochemical platform based on bromocresol green for the selective detection of atropine

  3. Selective screening of synthetic cathinones, amphetamines, piperazines, and phenethylamines using voltammetry

  4. Electrochemistry of the synthetic tryptamine 5-MeO-MiPT at glassy carbon and screen-printed electrodes

  5. Novel colorimetric-electrochemical methods for selective identification and quantification of Scopolamine

  6. Use of a lab-made disposable screen-printed sensor with boron-doped diamond for N-ethylpentylone detection

  7. Combined colorimetric and electrochemical screening method for selective detection of MDMA

  8. Electrochemical methods for determination of acetaminophen in biological matrices: a critical review

  9. Selective screening of NBOHs, NBOMes, and LSD using a 3D-Printed electrochemical double cell

  10. Electrochemical detection of mephedrone using a graphene screen-printed electrode

  11. Electrochemical method for detecting synthetic cannabinoids in e-cigarette and biological samples

  12. Chemically deposited boron-doped diamond screen-printed electrodes for manganese detection

  13. Colorimetric-Electrochemical Combined Method for Detection of Drugs in Blotter Papers

  14. SMART 3D-printed electrochemical cell for on-site and forensic analysis

  15. Oxygen plasma-treated graphite sheet electrodes for methamphetamines

  16. Fast screening of MDEA using carbon screen-printed electrode and voltammetry

  17. Electrochemical detection of 1-benzylpiperazine on carbon screen-printed electrode

  18. Screening method for detection of 1-(3-chlorophenyl)piperazine in forensic samples

  19. Selective screening method for MDPT using carbon nanofiber screen-printed electrodes

  20. Detection of LSD in forensic samples using carbon nanotube screen-printed electrodes

  21. Detection of 2C-B using environmentally friendly screen-printed electrodes

  22. Professional biography of Dorothy Hodgkin – Contributions to Chemistry, Biology, and Biochemistry

Conclusion

Larissa MagalhĂŁes de Almeida Melo exemplifies the next generation of analytical chemists committed to real-world impact in forensic science. Her research bridges engineering and chemistry to develop innovative, portable, and sustainable methods for drug detection. With international experience, strong academic output, and cross-disciplinary skills, she is well-positioned for leadership in global forensic chemistry research.

 

Bibhas Kumar Dutta | Spectroscopy | Best Researcher Award

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Assist. Prof. Dr. Bibhas Kumar Dutta | Spectroscopy | Best Researcher Award

Assistant Professor at Sree Chaitanya College, India

Dr. Bibhas Kumar Dutta is an Assistant Professor in the Department of Physics at Sree Chaitanya College, Habra, affiliated with West Bengal State University. With over two decades of experience in theoretical and experimental physics, Dr. Dutta has made significant contributions to quantum optics, nonlinear optics, atomic physics, and coherent control in atomic systems. He earned his Ph.D. in Physics from Vidyasagar University in 2010, after completing B.Sc. and M.Sc. degrees from the University of Calcutta. Dr. Dutta has authored more than 40 research papers published in reputed international journals, with an h-index of 9 and over 330 citations. He is an active collaborator in interdisciplinary research and regularly mentors undergraduate and postgraduate students. Known for his depth in multi-wave-mixing processes and quantum coherence, Dr. Dutta continues to influence the field with pioneering work in optical phase control and atom localization.

Professional Profile

Scopus

Education 

Dr. Bibhas Kumar Dutta has a strong academic background in physics. He completed his B.Sc. in Physics from the University of Calcutta in 1995, followed by an M.Sc. in Physics from the same university in 1997. His postgraduate education was marked by a solid foundation in theoretical and experimental physics. In recognition of his academic excellence, he was awarded the National Scholarship at both the 10+2 and graduation levels. In 2000, he qualified for the CSIR-NET with Junior Research Fellowship (JRF), a highly competitive national-level examination in India. He subsequently earned his Ph.D. in Physics from Vidyasagar University in 2010, where his research focused on quantum optics and coherent atomic systems. His educational journey reflects a consistent trajectory of academic excellence and deep engagement in frontier areas of physics.

Professional Experience

Dr. Bibhas Kumar Dutta has served as an Assistant Professor in the Department of Physics at Sree Chaitanya College, Habra, for over a decade. Affiliated with West Bengal State University, his academic role includes teaching undergraduate physics, mentoring research projects, and guiding students in their academic development. Prior to his Ph.D., he was actively involved in collaborative research projects in spectroscopic analysis and optical physics. His academic career is distinguished by his research on light-matter interaction, multi-wave mixing, and coherent control in atomic and optical systems. Over the years, Dr. Dutta has collaborated with numerous eminent scientists and published extensively in international peer-reviewed journals. He also contributes as a reviewer for journals and frequently participates in national and international physics conferences. His balanced commitment to both teaching and research makes him a respected figure in the academic community.

Awards and Honors 

Dr. Bibhas Kumar Dutta has received several academic honors throughout his career. Notably, he was awarded the National Scholarship at both the higher secondary and undergraduate levels, recognizing his exceptional academic performance in early education. He qualified for the prestigious CSIR-NET with Junior Research Fellowship (JRF) in 2000, which enabled him to pursue advanced research in theoretical physics. Over the years, his scholarly work has gained attention in the scientific community, with more than 330 citations and an h-index of 9. His contributions to quantum optics and nonlinear phenomena have been acknowledged through his involvement in high-impact journals like Scientific Reports, Physical Review, Journal of Physics B, and Optics Communications. He has also served as a co-author and collaborator with various prominent physicists in India. While not yet a recipient of large-scale research grants, his consistent publication record and collaborative work mark him as a recognized expert in his field.

Research Interests 

Dr. Bibhas Kumar Dutta’s research interests lie in the domains of quantum optics, atomic and molecular physics, nonlinear optics, and coherent control techniques in atomic systems. He is particularly focused on studying multi-wave mixing phenomena, atom localization, quantum interference effects, and optical phase modulation. His work also includes the development of novel methods for spatial light modulation using structured light fields, vortex beams, and four-wave mixing processes. Dr. Dutta has investigated phase-coherent processes for controlling absorption, dispersion, and spontaneous emission in various atomic configurations. His interests extend to applications in quantum information science, high-precision spectroscopy, and optical communication technologies. With a deep understanding of atomic coherence, he aims to develop new techniques for manipulating quantum states in both cold and hot atomic ensembles. His research is both theoretical and semi-experimental, involving simulations and modeling based on realistic quantum systems and nonlinear media.

Research Skills 

Dr. Dutta possesses a diverse set of research skills centered around theoretical modeling and computational simulations in quantum optics and atomic physics. He has expertise in density matrix formalism, perturbative and non-perturbative methods, and solving complex differential equations related to atom-light interactions. He is proficient in using scientific programming tools such as MATLAB and Mathematica for simulating absorption spectra, coherence effects, and spatial localization patterns. Dr. Dutta is skilled in analyzing spontaneous emission, multi-photon interactions, and nonlinear optical effects in multi-level atomic systems. He also demonstrates strong analytical skills in phase engineering, optical trapping, and waveguide dynamics. His collaborative research has involved simulating phenomena like Autler-Townes splitting, Fano resonance, and PT symmetry breaking. With a background that includes experimental spectroscopy, he can bridge theoretical predictions with potential experimental verification, making his research highly impactful and practically oriented.

Publication Top Notes

  1. Dutta B.K. & Panchadhyayee P. (2025) – A new mechanism of off-axis helical phase engineering in spatial four-wave-mixing light at frequency up-conversion regime

  2. Panchadhyayee P., Banerjee A., & Dutta B.K. (2024) – Vortex beam induced spatial modulation of quantum-optical effects in a coherent atomic medium

  3. Banerjee A., Panchadhyayee P., & Dutta B.K. (2024) – Efficient control of three-dimensional atom localization via probe absorption in a phase-coherent atomic medium

  4. Banerjee A., Panchadhyayee P., & Dutta B.K. (2024) – Efficient control of high-precision three-dimensional atom localization via probe absorption in a five-level phase-coherent atomic system

  5. Dutta B.K. & Panchadhyayee P. (2023) – Generation of optical PT-antisymmetry in a coherent N-type atomic medium

  6. Panchadhyayee P. & Dutta B.K. (2022) – Spatially structured multi-wave-mixing induced nonlinear absorption and gain in a semiconductor quantum well

  7. Dutta B.K. et al. (2020) – Optical absorption microscopy of localized atoms at microwave domain

  8. Dutta B.K. et al. (2020) – Multi-wave-mixing-induced nonlinear modulation of diffraction peaks in an opto-atomic grating

  9. Dutta B.K. & Panchadhyayee P. (2020) – Fano-like interference induced modification of Autler-Townes doublet spectrum

  10. Panchadhyayee P. et al. (2019) – Field-induced superposition effects on atom localization via resonance fluorescence spectrum

  11. Dutta B.K. & Panchadhyayee P. (2018) – Modification of optical properties by adiabatic shifting of resonances in a four-level atom

  12. Dutta B.K. et al. (2018) – Role of tunneling induced coherence in modulation of absorption and dispersion in a quantum dot molecule

  13. Panchadhyayee P. et al. (2018) – Resonance fluorescence microscopy via three-dimensional atom localization

  14. Dutta B.K. & Panchadhyayee P. (2016) – Modification and control of coherence effects in spontaneous emission spectrum

  15. Bayal I. et al. (2015) – Multiphoton-process-induced coherence effects in a dissipative quantum system

  16. Bayal I. et al. (2015) – Simulation of coherently controlled population dynamics in a three-level atomic system

  17. Dutta B.K. (2014) – Fano-like line shape of spontaneous emission spectrum in a weakly driven two-level atom

  18. Dutta B.K. (2013) – Coherent control of narrow structures in absorption, transparency and dispersion

  19. Bayal I. et al. (2013) – Modulation of spatial propagation dynamics in a three-core linear directional coupler

  20. Dutta B.K. et al. (2013) – Coherent control of localization of a three-level atom

Dr. Victoria Varchenko | Analytical Chemistry Award | Best Researcher Award

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Dr. Victoria Varchenko | Analytical Chemistry Award | Best Researcher Award

Dr. Victoria Varchenko ,Institute of Functional Materials Chemistry of State Scientific Institution “Institute for Single Crystals” of NAS of Ukraine , Ukraine

Victoria Varchenko is a skilled analytical chemist whose expertise lies in electrochemical methods and nanoparticle characterization. He completed her Ph.D. in Analytical Chemistry  at  Institute for Single Crystals, Ukraine, under Dr. K.N. Belikov. Her doctoral research focused on modified carbon paste electrodes for voltammetric determination of indole compounds, a vital area in analytical chemistry. Varchenko has contributed to the development of advanced procedures for preconcentration, sorption, and microextraction. he currently holds a position as Research Associate at the same institute, where he applies her deep knowledge of voltammetry, electrochemical transformations, and inductively coupled plasma optical emission spectrometry (ICP-OES). Her work significantly impacts the accuracy and efficiency of analytical chemistry techniques, especially in complex environmental and biological sample analysis.

Professional Profile:

Orcid

Scopus

Summary of Suitability for Award:

Victoria Varchenko’s qualifications, experience, and research contributions make her a strong candidate for the “Best Researcher Awards.” Her educational background includes a Ph.D. in Analytical Chemistry from the State Scientific Institution “Institute for Single Crystals” of the National Academy of Sciences of Ukraine, with a focus on modified carbon paste electrodes for the voltammetric determination of electroactive indole compounds. Her research in this area shows innovation in analytical chemistry, specifically in voltammetry, and her expertise in preconcentration, separation, microextraction, and electrochemical transformation of organic substances demonstrates a deep understanding of complex chemical processes.

🎓Education:

Victoria Varchenko obtained her Ph.D. in Analytical Chemistry from the Institute for Single Crystals, Ukraine, in  under the guidance of Dr. K.N. Belikov. Her thesis, titled Modified Carbon Paste Electrodes for Voltammetric Determination of Electroactive Indole Compounds, significantly contributed to the field of electrochemical analysis. Before pursuing her doctoral degree, she earned a Master of Science in Chemistry from V.N. Karazin Kharkov National University in  specializing in chemical metrology. This foundational training provided her with a deep understanding of analytical techniques and quality control processes. Varchenko’s education has equipped her with the skills necessary to develop innovative solutions to complex analytical challenges, especially in the areas of voltammetry, sorption, and microextraction.

🏢Work Experience:

Victoria Varchenko has a rich background in analytical chemistry, with over eight years of experience at the State Scientific Institution “Institute for Single Crystals” of the National Academy of Sciences of Ukraine. She started her career there as a Junior Research Associate , where she focused on developing and validating analytical procedures, particularly in microextraction, voltammetry, and sorption techniques. In 2020, she was promoted to Research Associate, where she continues to focus on advanced applications of electrochemical methods, including the study of organic substances’ electrochemical transformations. Varchenko’s work also involves the use of inductively coupled plasma optical emission spectrometry (ICP-OES) for comprehensive analysis of diverse sample types. Her experience spans various research areas, including nanoparticle synthesis, voltammetric analysis, and analytical quality control, positioning her as an expert in her field.

🏅Awards:

Victoria Varchenko has received recognition for her significant contributions to the field of analytical chemistry, particularly for her innovative research on electrochemical techniques. Though specific awards are not detailed, her work is highly regarded in the scientific community, with multiple publications in peer-reviewed journals. Her research, including the development of modified carbon paste electrodes for indole compound determination, has been instrumental in advancing analytical chemistry techniques. Additionally, her work on microextraction and sorption in environmental analysis has been well-received. Varchenko has been an active contributor to quality control advancements in chemical analysis, further demonstrating her impact on the field. Her work is supported by her position as a Research Associate at a leading institution, reflecting the esteem with which she is regarded by her peers.

🔬Research Focus:

Victoria Varchenko’s primary research interests lie in advancing analytical chemistry techniques, with a particular focus on preconcentration, separation methods, and electrochemical analysis. She specializes in developing and applying modified carbon paste electrodes for voltammetric determination of electroactive organic compounds. Her work in microextraction and sorption has led to enhanced sample preparation methods, improving the efficiency and accuracy of analytical testing. Varchenko is also involved in nanoparticle synthesis and characterization, areas that are increasingly important in environmental and biological analysis. Furthermore, she applies inductively coupled plasma optical emission spectrometry (ICP-OES) for the comprehensive analysis of complex samples, such as environmental and agricultural products. Varchenko’s research is aimed at creating more efficient, accurate, and environmentally friendly analytical methods, with applications in fields like environmental monitoring and health diagnostics.

Publication Top Notes:

  • Differential-Pulse Polarographic Determination of Periciazine by Hydrogenperoxymonofulfate Treatment
  • Menthol-Based (Deep) Eutectic Solvents: A Review on Properties and Application in Extraction
    • Cited by: 13
  •  Application of Cloud-Point Extraction for the Determination of Arsenic using Inductively Coupled Plasma Atomic Emission Spectrometry in Several Pharmaceutical Preparations
  • : Grafting of phosphorus-containing tetrahydroxy(thia)calixarenes on silica enhances europium(III) adsorption
    • Cited by: 3
  • Study on the sorption properties of (NH4)2TiOF4 particles
    • Cited by: 3

 

 

 

 

Mr. Lei Mou | Analytical Chemistry Award | Young Scientist Award

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Mr. Lei Mou | Analytical Chemistry Award | Young Scientist Award

Mr. Lei Mou ,Guangzhou Medical University, China

Lei Mou is a Research Associate at the Terasaki Institute for Biomedical Innovation, Los Angeles, specializing in biosensors, wearable devices, and organ-on-a-chip technology. With a robust background in biomedical engineering and materials science, Lei completed a Ph.D. from the National Center for Nanoscience and Technology (NCNST) under Prof. Xingyu Jiang. His work integrates advanced microfluidic and biosensor platforms aimed at enhancing clinical diagnostics and wearable health monitoring. With extensive research and technical skills, he has contributed to innovative approaches in immunoassay technology, HPV detection, and biosignal computing. Lei’s contributions to nanobiotechnology are also reflected in his numerous patents, high-impact publications, and presentations at international conferences.

Professional Profile:

Google Scholar

Summary of Suitability for Award:

Lei Mou demonstrates strong potential for the “Young Scientist Award,” with impressive accomplishments in biomedical engineering, especially in clinical biosensors, wearable devices, and organs-on-a-chip technology. His academic foundation is rooted in a Ph.D. from the Chinese Academy of Sciences, where he specialized in biomaterials and point-of-care diagnostic platforms, laying a solid groundwork for his current innovative research.

🎓Education:

Lei Mou earned his Ph.D. in Biomedical Engineering from the National Center for Nanoscience and Technology, Chinese Academy of Sciences (2016-2020), where he researched biosensors and microfluidic devices under Prof. Xingyu Jiang’s mentorship. His undergraduate studies in Materials Science and Engineering were completed at the University of Science and Technology Beijing (USTB) in 2016, as part of the Excellent Engineer Training Program. Here, he laid the foundation for his expertise in nanomaterials and engineering design, achieving numerous accolades for academic excellence. Lei’s educational path has emphasized interdisciplinary research, equipping him with a skill set to bridge materials science, biomedical engineering, and clinical applications effectively.

🏢Work Experience:

Lei Mou is currently a Research Associate at the Terasaki Institute for Biomedical Innovation (TIBI), where he focuses on the development of organ-on-a-chip systems and advanced biosensors. Prior to this, he was a Researcher at the Third Affiliated Hospital of Guangzhou Medical University, where he specialized in clinical biosensors and wearable device technology. Lei’s professional experience has enabled him to develop high-sensitivity immunoassay platforms and contribute to significant projects in health-related microfluidic applications. His work bridges clinical settings and advanced engineering, bringing laboratory innovations closer to real-world applications.

🏅Awards:

Lei Mou has earned numerous awards for his academic and research excellence, including the Director’s Scholarship at NCNST and the First Class Scholarship for Master’s Students, recognizing him as a top 3% student. During his undergraduate studies, he received the prestigious 86 Alumni Scholarship, the National Scholarship from China’s Ministry of Education, and the Beijing Outstanding Graduates Award. His achievements reflect his commitment to excellence and innovation in his field, with honors that highlight his performance and contributions to biomedical engineering and materials science.

🔬Research Focus:

Lei Mou’s research focuses on microfluidic immunoassays, wearable biosensors, and organs-on-a-chip technologies. He specializes in integrating nanotechnology with biomedical engineering to develop advanced diagnostic tools for healthcare. His work includes creating chemiluminescence immunoassay platforms that amplify biomarker signals using gold nanoparticles, as well as developing portable devices for detecting high-risk HPV strains. His research has significant implications for personalized medicine and remote diagnostics, aiming to improve accessibility and precision in clinical diagnostics and healthcare monitoring.

Publication Top Notes:

  • Surface chemistry of gold nanoparticles for health-related applications
    • Citations: 277
  • Microfluidics‐based biomaterials and biodevices
    • Citations: 183
  • Materials for microfluidic immunoassays: a review
    • Citations: 154
  • Printable metal-polymer conductors for highly stretchable bio-devices
    • Citations: 130
  • Highly stretchable and biocompatible liquid metal‐elastomer conductors for self‐healing electronics
    • Citations: 109