Issa Sali | Biophysics | Distinguished Scientist Award

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Dr. Issa Sali | Biophysics | Distinguished Scientist Award

Senior Lecturer at University of Maroua, Cameroon

Dr. Issa Sali 🇨🇲, born on July 26, 1983, in Garoua, Cameroon, is a distinguished senior lecturer at the University of Maroua’s National Advanced School of Mines and Petroleum Industries 🏫. A biophysicist by training, Dr. Sali holds a Ph.D. in Biophysics from the University of Yaounde I, where he explored energy transport in alpha-helix proteins 🧬. With a background blending physics, biophysics, and education, his academic path reflects a strong foundation in both scientific theory and teaching methodology 📘. He has taught extensively in both secondary schools and higher education institutions, engaging students in subjects ranging from biomechanics to thermodynamics. Passionate about nonlinear systems, biofuels, and the mathematical modeling of biological processes, his research traverses frontiers in applied physics and biophysical simulations 🔬. He also actively participates in international workshops and conferences, representing a promising voice in African scientific development 🌍. Dr. Sali is an enthusiastic researcher and mentor who bridges science and education seamlessly.

Publications Top Notes 

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🎓 Education 

Dr. Issa Sali’s academic trajectory reflects a strong passion for physics and biophysics 📚. He earned his Ph.D. in Biophysics in 2019 from the University of Yaounde I 🏛️, where he focused on the dynamics of excitons and energy transport in alpha-helix proteins 🧬. Prior to that, he acquired a Master’s degree in Biophysics in 2012 from the same university, researching nonlinear effects in biological macromolecules 🌿. Complementing his scientific credentials, he also obtained a Secondary School Teacher’s Diploma in 2013 from the Higher Teachers Training College, reflecting his dual commitment to science and pedagogy 👨‍🏫. His academic journey began with a Bachelor’s degree in Physics in 2006 from the University of Ngaoundéré, Cameroon 🔭. This well-rounded academic background not only laid a solid foundation for his research but also shaped his distinctive blend of education, modeling expertise, and scientific inquiry, setting him apart in the fields of complex systems and biophysics 🧠.

👨‍🏫 Professional Experience 

Dr. Issa Sali currently serves as a Senior Lecturer at the Department of Refining and Petrochemistry, National Advanced School of Mines and Petroleum Industries, University of Maroua 🛢️. Since 2019, he has contributed significantly to higher education, teaching units such as biomechanics, thermodynamics, fluid mechanics, and numerical methods 📈. His academic versatility covers first to fourth-year undergraduate levels, showing his broad command of technical and applied sciences. Prior to this, from 2013 to 2019, Dr. Sali worked as a high school teacher in physical sciences and technologies at Lycée Moderne d’Ongot, Mbankomo 🏫. His transition from secondary to tertiary education reflects an upward trajectory marked by dedication and the drive to influence future scientists 👨‍🔬. His lectures blend theoretical foundations with computational tools like MATLAB and numerical schemes, ensuring his students are well-equipped for modern scientific challenges ⚙️. His teaching reflects both scholarly rigor and a passion for applied problem-solving.

🔬 Research Interests 

Dr. Issa Sali’s research is a fascinating mix of physics, biology, and mathematics, deeply rooted in the study of nonlinear and complex systems 🔄. His work on solitons, excitons, and protein dynamics bridges theoretical physics with real-world biological behavior 🧪. He explores topics like DNA and protein modeling, virus dynamics (Hepatitis B and C), and microbial enhanced oil recovery (MEOR) ⛽ using mathematical equations. His interest also spans emerging disease modeling (SIR and prey-predator systems), showing relevance to epidemiology and public health 📉🧬. Dr. Sali delves into biomechanics and nonlinear modeling of biological structures, focusing on how complex patterns emerge and evolve in living systems. His dual expertise in computational methods and applied physics enables high-impact simulation and analysis 💻. Additionally, his involvement in biofuel generation research underlines a sustainable, interdisciplinary vision 🌱. Altogether, his research reflects intellectual curiosity, societal impact, and a strong commitment to scientific problem-solving 🔍.

🏆 Awards and Honors  

While no specific awards have been listed in his profile, Dr. Issa Sali’s achievements are evident through his active participation in international scientific forums and institutions 🌍. Notably, he was a speaker at the “Conference on Generation of Biofuels” during the International Fair for Young African Researchers in December 2020, showcasing his contributions to sustainable energy discourse 🔋. Earlier, in 2011, he attended the prestigious “International School on Nonlinear Dynamics in Complex Systems” hosted by The Abdus Salam International Centre for Theoretical Physics 🏅. These engagements highlight his recognition as a thought leader in emerging and interdisciplinary fields. His consistent involvement in academic conferences reflects a career of scholarly excellence and growing impact. Such honors demonstrate that his work is appreciated not only in Cameroon but across the global scientific community 🌐. His dedication to both science and education positions him as a rising star in the field of biophysical modeling and sustainable development.

Publications Top Notes 

1. Pattern formations in nonlinear dynamics of hepatitis B virus

  • Authors: B.T. Mbopda, S. Issa, S. Abdoulkary, R. Guiem, H.P. Fouda

  • Year: 2021

  • Source: The European Physical Journal Plus, 136(5), Article 586

  • Summary: This study investigates the spatiotemporal dynamics of hepatitis B virus (HBV) infection through pattern formation. The model incorporates reaction-diffusion equations representing prey–predation, competition, and commensalism interactions among species. The analysis reveals the conditions under which spatial patterns emerge, providing insights into HBV infection dynamics.

2. Fluctuations of polarization induce multisolitons in α-helix protein

  • Authors: S. Issa, C.B. Tabi, H.P. Ekobena Fouda, T.C. Kofané

  • Year: 2018

  • Source: Nonlinear Dynamics, 91(1), 679–686

  • Summary: The paper explores how polarization fluctuations can lead to the formation of multisoliton structures in α-helix proteins. By modeling the dynamics of amide-I vibrations coupled with lattice deformations, the study demonstrates the conditions under which stable multisoliton solutions can exist, contributing to the understanding of energy transport in protein structures.

3. Long-range modulated wave patterns in certain nonlinear saturation alpha-helical proteins

  • Authors: S. Issa, I. Maïna, C.B. Tabi, A. Mohamadou, H.P.E. Fouda, T.C. Kofané

  • Year: 2021

  • Source: The European Physical Journal Plus, 136(9), Article 900

  • Summary: This research examines the dynamics of modulated solitary wave patterns in alpha-helical proteins, considering long-range dipole–dipole interactions. The study extends beyond nearest-neighbor interactions, revealing how these long-range effects influence the formation and stability of solitary waves, which are crucial for understanding energy transport in biological systems.

4. Three excitons states in nonlinear saturation α-helix protein

  • Authors: S. Issa, C.B. Tabi, H.P. Ekobena Fouda, T.C. Kofané

  • Year: 2018

  • Source: The European Physical Journal Plus, 133(6), Article 233

  • Summary: The study focuses on the existence of three distinct exciton states in nonlinear saturation α-helix proteins. By analyzing the nonlinear dynamics and saturation effects, the authors identify conditions that support the formation of these exciton states, which are essential for understanding energy localization and transfer in protein molecules.

5. Modulational instability in a biexciton molecular chain with saturable nonlinearity effects

  • Authors: I. Sali, C.B. Tabi, H.P. Ekobena, T.C. Kofané

  • Year: 2016

  • Source: International Journal of Modern Physics B, 30(1), 1550244

  • Summary: This paper investigates the modulational instability (MI) in a biexciton molecular chain, accounting for saturable nonlinearity effects. The analysis reveals how saturation influences the stability of wave solutions, providing insights into the conditions that lead to the formation of localized structures in molecular chains.

6. Complex Ginzburg–Landau equation in the modified Peyrard–Bishop–Dauxois model

  • Authors: H. Ngoubi, I. Sali, G.H. Ben-Bolie, T.C. Kofané

  • Year: 2023

  • Source: The European Physical Journal Plus, 138(9), Article 842

  • Summary: The authors derive a complex Ginzburg–Landau equation from the modified Peyrard–Bishop–Dauxois model using a semidiscrete approximation. This equation describes the dynamics of motion in DNA molecules, offering a framework to study nonlinear excitations and their stability in biophysical systems.

7. Travelling waves of a nonlinear reaction-diffusion model of the hepatitis B virus

  • Authors: B.T. Mbopda, S. Issa, R. Guiem, S.C.O. Noutchie, H.P. Ekobena

  • Year: 2023

  • Source: The European Physical Journal Plus, 138(11), Article 971

  • Summary: This study presents a mathematical model of HBV infection incorporating healthy cells, infected cells, and free viruses, along with spatial mobility and drug treatment effects. By analyzing traveling wave solutions, the paper provides insights into the spread and control of HBV infections.

8. Diffusion effects in nonlinear dynamics of hepatitis B virus

  • Authors: S. Issa, B.M. Tamko, B. Dabolé, C.B. Tabi, H.P.F. Ekobena

  • Year: 2021

  • Source: Physica Scripta, 96(10), 105217

  • Summary: The paper investigates a dynamic system modeling HBV infection, considering diffusion effects among healthy cells, infected cells, and free viruses. The model, governed by equations representing prey-predation, competition, and commensalism, reveals exact traveling wave solutions, enhancing the understanding of HBV dynamics.

9. Multi-exciton transfer in a biomolecular system

  • Authors: H. Ngoubi, I. Sali, A. Mvogo, G.H. Ben-Bolie, T.C. Kofané

  • Year: 2024

  • Source: Nonlinear Dynamics, 112(5), 3887–3901

  • Summary: This research explores the mechanisms of multi-exciton transfer in biomolecular systems. By modeling the interactions and transfer processes, the study sheds light on the conditions facilitating efficient energy transport, which is vital for understanding various biological functions.

10. Diffusive pattern formations in three-species nonlinear dynamics of cancer

  • Authors: S. Issa, B.T. Mbopda, G.R. Kol, C.B. Tabi, H.P. Fouda

  • Year: 2023

  • Source: The European Physical Journal Plus, 138(6), Article 496

  • Summary: The study examines pattern formations in a tumor growth model involving healthy cells, cancer cells, and acid concentrations. Using three-species reaction–diffusion equations, the authors determine equilibrium points and apply the Routh–Hurwitz criteria to assess system stability and the existence of Turing patterns.

Conclusion 

In conclusion, Dr. Issa Sali stands as a committed scholar, educator, and researcher, contributing richly to the academic and scientific landscapes of Cameroon and beyond 🌍. His background in biophysics, mathematical modeling, and complex systems equips him with the tools to explore pressing questions in science and society 🔬📊. Whether it’s through teaching the next generation of engineers or investigating the dynamics of proteins and microbial oil recovery, Dr. Sali continues to bridge theory and application with finesse. His participation in international platforms speaks to his global vision, while his educational achievements affirm his deep-rooted commitment to lifelong learning and academic excellence 🎓💡. Dr. Sali’s interdisciplinary expertise, combining physics, biology, and computational science, positions him uniquely to address the challenges of energy, health, and education in the 21st century 🌿⚡. He is a shining example of innovation and dedication in Africa’s scientific renaissance and a role model for future generations of scholars.

Sanjai Karanth | Biophysics | Best Researcher Award

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Dr. Sanjai Karanth | Biophysics | Best Researcher Award

Postdoctoral Researcher at Leibniz Institute for Food Systems Biology at Technical University Munich, Germany

Dr. Sanjai Karanth is a dynamic biophysicist with a multidisciplinary background that fuses biotechnology, software engineering, and cutting-edge biophysical chemistry 🔬💡. His professional journey spans globally acclaimed institutes in Germany and the USA, where he’s contributed to frontier research on mechanoreceptors, DNA-lipid nanodiscs, and nanoparticle-biomembrane interactions 🌱🧪. A blend of academic excellence and industrial expertise, Sanjai’s work reflects deep curiosity and technical dexterity. His transition from software engineering at Wipro to award-winning research demonstrates adaptability and passion for science 🔄🧠. With a poster prize at the Linz Winter Workshop and scholarships funded by the German Federal Ministry, Sanjai is emerging as a promising scientist in interface biophysics and sensory chemistry 🌍🏅. His collaborative spirit, cross-domain experience, and global exposure equip him to contribute to innovations in sustainable food systems and membrane biochemistry.

Professional Profile

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🎓 Education

Dr. Sanjai Karanth’s academic voyage began with a Bachelor of Engineering in Biotechnology from DSCE, Bengaluru, where he laid the foundation of his scientific interests 🧫🎓. Excelling with a 76.4% grade, he pursued a Master’s in Biophysics at Ulm University, Germany 🇩🇪, where his thesis on light transmission spectroscopy reflected early signs of his analytical depth 💡🔬. He graduated with a CGPA of 2.4 under the German grading system. His academic peak was reached during his PhD at the University of Greifswald, focusing on the physicochemical interactions of proteins and nanoparticles under nitric oxide stress—a niche and impactful topic in biophysical chemistry ⚗️🧬. Under Prof. Mihaela Delcea’s guidance, his doctoral research combined interface dynamics, nanoscience, and membrane biochemistry, forming the scientific bedrock of his postdoctoral work. Sanjai’s education trajectory reveals a commitment to science that is both deep and multidisciplinary.

🧪 Professional Experience

Dr. Sanjai Karanth has accumulated robust international research experience that spans the United States and Germany 🌍🔍. Currently a Postdoctoral Researcher at the Leibniz Institute for Food Systems Biology at TUM, he delves into the sensory realm of mouthfeel, focusing on plant-based texture-enhancers through biophysical identification of receptors 🌱👄. Previously, at Kent State University (USA), he worked on engineering DNA-lipid nanodiscs—a cutting-edge tool in structural biology 🧬🔬. At the University of Greifswald, he investigated how plastic nanoparticles interact with blood proteins and lipid membranes, contributing to the evolving field of environmental biophysics 🌐🧫. Earlier, Sanjai also served in the corporate realm at Wipro Technologies, evolving from Software Engineer to Quality Assurance Team Lead 🖥️🔧. His ability to lead teams, handle client deliverables, and translate business needs into code highlights an interdisciplinary aptitude uncommon in many academic researchers.

🔬 Research Interests

Dr. Sanjai Karanth’s research interests converge at the intersection of biomolecular interfaces, nanotechnology, and sensory biophysics 🔍🧪. His fascination lies in exploring how biomolecules behave under physical and chemical stresses—especially in lipid bilayers, membrane proteins, and nano-bio interactions. Whether it’s decoding how nanoparticles influence blood components or how texture is sensed at the molecular level in plant-based foods, Sanjai thrives on bridging fundamental science with real-world applications 🌾👨‍🔬. His postdoctoral studies have advanced the understanding of mechanoreceptors and chemoreceptors, essential for innovating sustainable food systems 🌱🧠. Earlier, he explored nitric oxide-induced stress on biomimetic membranes during his PhD—laying the groundwork for his multidisciplinary approach. By integrating spectroscopy, nanodisc technology, and physicochemical assays, Sanjai seeks to demystify complex interactions that underlie both health and sensory science 🧬👅. His ambition lies in continuing to unravel molecular secrets that have societal, environmental, and nutritional relevance.

🏅 Awards and Honors

Dr. Sanjai Karanth’s scientific journey has been punctuated with notable recognitions 🏆📚. In 2025, he secured the 3rd Prize for his poster at the Linz Winter Workshop in Austria—a testament to the relevance and quality of his biophysical research ❄️🔬. Earlier, in 2016, he was honored with a prestigious scholarship from Ulm University, funded by Germany’s Federal Ministry of Education and Research (BMBF), enabling him to pursue advanced biophysics research 💶🎓. His excellence wasn’t confined to academia—during his time at Wipro Technologies, he was celebrated as an Outstanding Team Player in 2014, a recognition of his leadership and teamwork skills in the IT sector 🌐💼. These accolades span both technical and interpersonal domains, demonstrating Sanjai’s rare ability to excel in collaborative environments across science and industry. Each award not only honors past achievement but also reflects his potential to contribute meaningfully to future scientific innovation.

Publications Top Notes 

1.Title: Biomolecular and biophysical AFM probing reveals distinct binding of bitter peptide VAPFPEVF to TAS2R16 without inducing an intracellular calcium response
Authors: Phil Richter, Sanjai Karanth, Rita dos Santos Natividade, Alessandro Nicoli, Małgorzata M. Kogut-Guenthel, Julia Benthin, Antonella Di Pizio, Melanie Koehler, Veronika Somoza
Year: 2025
Citation: Food Chemistry, Vol. 484, 2025, Article 144448
Source: DOI: 10.1016/j.foodchem.2025.144448
Summary:
This study used atomic force microscopy (AFM) to demonstrate that the bitter peptide VAPFPEVF binds specifically to the human bitter taste receptor TAS2R16 but does not trigger the typical intracellular calcium signaling. Instead, it affects cAMP pathways in gastric cells, suggesting alternative signaling mechanisms for taste perception.

2.Title: Fava Bean Protein Nanofibrils Modulate Cell Membrane Interfaces for Biomolecular Interactions as Unveiled by Atomic Force Microscopy
Authors: Sanjai Karanth
Year: 2024
Citation: Foods, 13(21), 2024
Source: DOI: 10.3390/foods13213411
Summary:
Explores how fava bean protein nanofibrils interact with cell membranes, altering biomolecular interfaces. AFM imaging revealed the structural changes at the membrane interface, advancing understanding of plant protein interactions at the cellular level.

3.Title: The path to the G protein‐coupled receptor structural landscape: Major milestones and future directions
Authors: Not specified
Year: 2024
Citation: British Journal of Pharmacology, 2024
Source: DOI: 10.1111/bph.17314
Summary:
A comprehensive review summarizing significant progress in the structural biology of G protein-coupled receptors (GPCRs), highlighting key milestones and potential future research directions in receptor pharmacology.

4.Title: Nanodisc Technology: Direction toward Physicochemical Characterization of Chemosensory Membrane Proteins in Food Flavor Research
Authors: Sanjai Karanth
Year: 2024
Citation: Journal of Agricultural and Food Chemistry, 2024
Source: DOI: 10.1021/acs.jafc.4c01827
Summary:
Discusses the use of nanodisc technology to stabilize chemosensory membrane proteins for physicochemical characterization, with applications in understanding flavor perception and food chemistry.

5.Title: Biophysical investigations using atomic force microscopy can elucidate the link between mouthfeel and flavour perception
Authors: Sanjai Karanth
Year: 2024
Citation: Nature Food, 2024
Source: DOI: 10.1038/s43016-024-00958-3
Summary:
Highlights how atomic force microscopy can be employed to study biophysical interactions relevant to mouthfeel and flavor, shedding light on the molecular basis of sensory perception.

6.Title: Interaction of Polystyrene Nanoparticles with Supported Lipid Bilayers: Impact of Nanoparticle Size and Protein Corona
Authors: Sanjai Karanth
Year: 2023
Citation: Macromolecular Bioscience, 2023
Source: DOI: 10.1002/mabi.202200464
Summary:
Investigates how size and protein corona of polystyrene nanoparticles influence their interactions with model lipid membranes, providing insights into nanoparticle-biomembrane interactions important for nanotoxicology.

7.Title: Identification of a critical lipid ratio in raft-like phases exposed to nitric oxide: An AFM study
Authors: Sanjai Karanth
Year: 2021
Citation: Biophysical Journal, June 2021
Source: DOI: 10.1016/j.bpj.2021.06.009
Summary:
AFM was used to reveal how nitric oxide exposure affects the lipid composition and organization in membrane raft-like domains, which has implications for cellular signaling under stress conditions.

8.Title: Biopolymer-coated gold nanoparticles inhibit human insulin amyloid fibrillation
Authors: Sanjai Karanth
Year: 2020
Citation: Scientific Reports, December 2020
Source: DOI: 10.1038/s41598-020-64010-7
Summary:
Shows that biopolymer-coated gold nanoparticles can effectively inhibit the formation of insulin amyloid fibrils, offering potential therapeutic avenues for amyloid-related diseases.

9.Title: Changing surface properties of artificial lipid membranes at the interface with biopolymer coated gold nanoparticles under normal and redox conditions
Authors: Sanjai Karanth
Year: 2020
Citation: Biophysical Chemistry, December 2020
Source: DOI: 10.1016/j.bpc.2020.106465
Summary:
Examines how the interaction between biopolymer-coated gold nanoparticles and lipid membranes changes under normal and redox stress, providing insights into nanoparticle–membrane dynamics.

10.Title: Nitrosative stress affects the interaction of integrin alphaIIbbeta3 with its ligands
Authors: Sanjai Karanth
Year: 2020
Citation: Biochimica et Biophysica Acta (BBA) – Biomembranes, May 2020
Source: DOI: 10.1016/j.bbamem.2020.183198
Summary:
Studies how nitrosative stress modifies the binding of integrin alphaIIbbeta3 to its ligands, which can affect platelet function and blood coagulation processes.

🎯 Conclusion 

Dr. Sanjai Karanth exemplifies a new generation of interdisciplinary scientists—those who comfortably straddle the realms of computation, chemistry, and biology to solve complex problems 🌐🔬. From developing membrane models in Germany to crafting nanodiscs in the USA, and now shaping food texture perception in Bavaria, his trajectory illustrates global competence, scientific curiosity, and translational vision 🌍🧠. Backed by academic accolades and industrial experience, Sanjai brings both intellectual rigor and a practical mindset to every project he undertakes. As he continues to decode sensory and molecular systems at the forefront of science, Sanjai’s future looks rich with collaborative potential, societal relevance, and scientific breakthroughs 🚀🌿. His story is one of reinvention, cross-border achievement, and unwavering passion for biophysical chemistry. With each milestone, he reinforces his role as a researcher committed to understanding the invisible interactions that make our world work—right from the nanoscale to the sensory scale.