John Byrnes | Biochemistry, Genetics and Molecular Biology | Best Paper Award

Best Paper Award

Selective Inhibition of Proofreading Exonucleases The Central Role in Obesity Assoviated Carciniogenesis
John Byrnes
Affiliation University of Miami
Country United States
Article Title Selective Inhibition of Proofreading Exonucleases The Central Role in Obesity Assoviated Carciniogenesis
Google Scholar ID 1kizaHgAAAAJ&hl
Article Type Research Article
Article Views 870
Reference Count 88
Award Category Best Paper Award
Event International Research Excellence and Best Paper Awards
ORCID 0000-0003-0940-9710

The Best Paper Award recognizes the scholarly contribution of John Byrnes of the University of Miami for research examining the relationship between proofreading exonucleases and obesity-associated carcinogenesis. Published in MDPI during 2026, the study contributes to ongoing discussions in biochemistry, genetics, and molecular biology regarding genomic integrity, cancer development, and molecular mechanisms associated with metabolic disorders. The award acknowledges the scientific significance, methodological rigor, and interdisciplinary relevance of the publication within contemporary biomedical research.[1]

Abstract

This award-recognized research investigates the potential role of proofreading exonucleases in mechanisms associated with obesity-related carcinogenesis. The study explores how alterations in DNA replication fidelity, repair pathways, and genomic maintenance may contribute to cellular transformation under metabolic stress conditions. Through molecular and biochemical analyses, the research evaluates the consequences of selective exonuclease inhibition and its implications for tumor development. Findings provide insights into interactions between obesity-associated biological environments and genomic instability. The work advances understanding of cancer biology while identifying potential molecular targets for future therapeutic development and translational biomedical investigations.[2]

Keywords

AMP; AMPK; carcinogenesis; DNA polymerase; fidelity; energy regulation; metabolism; mutation; obesity; proofreading exonuclease.

Introduction

The increasing prevalence of obesity has intensified scientific interest in understanding its relationship with cancer risk and progression. Researchers have identified multiple biological pathways linking metabolic dysregulation to genomic instability. This study focuses on proofreading exonucleases, enzymes responsible for maintaining DNA replication accuracy, and evaluates their relevance within obesity-associated carcinogenic processes that may influence disease initiation and progression.[2]

Research Profile

John Byrnes is affiliated with the University of Miami and has established a research portfolio within biochemistry, genetics, and molecular biology. With 138 indexed scholarly documents, 8,573 citations, and an h-index of 39, his academic contributions demonstrate sustained engagement in molecular mechanisms underlying human disease, cancer development, and genomic maintenance processes across diverse biomedical research domains.[3]

Scientific Background

Proofreading exonucleases play a critical role in correcting replication errors and preserving genome integrity. Deficiencies in these enzymatic systems can result in elevated mutation rates and increased susceptibility to malignant transformation. Previous investigations have linked obesity-related inflammation, oxidative stress, and metabolic disturbances with DNA damage, creating a scientific basis for examining interactions between exonuclease activity and carcinogenic pathways.[4]

Methodology

The research applies molecular biology and biochemical methodologies to investigate the consequences of selective proofreading exonuclease inhibition. Experimental analyses assess cellular responses, genomic integrity markers, and mechanisms associated with DNA repair regulation. By integrating laboratory observations with established cancer biology frameworks, the study evaluates how altered proofreading functions may contribute to carcinogenic processes under obesity-associated physiological conditions.[2]

Key Findings

The study identifies significant relationships between proofreading exonuclease activity and mechanisms that influence genomic stability. Results indicate that disruptions in proofreading functions may enhance mutation accumulation and contribute to cellular environments favorable to carcinogenesis. The findings support the hypothesis that obesity-associated biological stressors can interact with genomic maintenance pathways, potentially increasing cancer susceptibility through complex molecular mechanisms.[2]

Scientific Contributions

This research contributes to the growing body of knowledge connecting metabolic disease and cancer biology. By highlighting proofreading exonucleases as important molecular components within obesity-associated carcinogenesis, the study offers a framework for future investigations into diagnostic biomarkers and therapeutic interventions. The work also strengthens interdisciplinary connections between molecular genetics, oncology, and translational biomedical science.[4]

Conclusion

The Best Paper Award recognizes a publication that advances understanding of molecular mechanisms underlying obesity-associated cancer development. Through examination of proofreading exonucleases and genomic stability pathways, the research provides valuable scientific insights with potential relevance to future therapeutic strategies. Its contribution to contemporary biomedical literature reflects both methodological rigor and significance within the broader field of molecular oncology.[5]

References

  1. MDPI. (2026). Selective Inhibition of Proofreading Exonucleases The Central Role in Obesity Assoviated Carciniogenesis.
    https://www.mdpi.com/1467-3045/48/4/346
  2. DOI Reference. Cell Biochemistry and Function, Volume 48, Issue 4.
    https://doi.org/10.3390/cimb48040346
  3. Google Scholar. (n.d.). John Byrnes Author Profile.
    https://scholar.google.com/citations?user=1kizaHgAAAAJ&hl=en&oi=sra
  4. MDPI. (2026). Journal Information and Publication Metadata.
    https://www.mdpi.com/
  5. International Research Excellence and Best Paper Awards. (2026). Best Paper Award Recognition Program.
    https://bestpaperawards.com/

Kayoomars Karami | Physics and Astronomy | Best Researcher Award

Best Researcher Award

Kayoomars Karami
University of Kurdistan

Kayoomars Karami
Affiliation University of Kurdistan
Country Iran
Scopus ID 22979495000
Documents 108
Citations 2,427
h-index 31
Subject Area Physics and Astronomy
Event International Research Excellence and Best Paper Awards
ORCID 0000-0003-0008-0090

The Best Researcher Award recognizes sustained scholarly achievement, research productivity, and scientific influence demonstrated through peer-reviewed publications, citations, and contributions to the advancement of knowledge. Kayoomars Karami of the University of Kurdistan has established a significant academic profile within Physics and Astronomy through extensive publication activity and measurable research impact. His scholarly record reflects continued engagement with theoretical and applied investigations that contribute to contemporary scientific discourse and international research development.[1]

Abstract

This article presents an academic overview of Kayoomars Karami and his suitability for recognition through the Best Researcher Award. Affiliated with the University of Kurdistan, Karami has developed a notable scholarly portfolio in Physics and Astronomy characterized by extensive publication output, substantial citation performance, and a strong h-index. His research activities have contributed to the advancement of theoretical understanding within key scientific domains while supporting international academic collaboration. The combination of documented productivity, measurable influence, and sustained research engagement demonstrates qualities commonly associated with distinguished scholarly achievement and research excellence in the contemporary scientific community.[1][2]

Keywords

Best Researcher Award, Kayoomars Karami, Physics and Astronomy, University of Kurdistan, Scientific Impact, Citation Analysis, Research Excellence, Scopus Author Profile, Scholarly Contributions, Academic Recognition.

Introduction

Recognition through academic awards often reflects a combination of research productivity, scientific influence, publication quality, and contributions to knowledge advancement. Researchers operating within highly specialized scientific disciplines are evaluated according to objective indicators such as citation records, publication volume, and scholarly visibility. Kayoomars Karami’s academic career demonstrates these characteristics through a substantial body of research and recognized contributions within Physics and Astronomy, supporting consideration for prestigious research distinctions.[1]

Research Profile

Kayoomars Karami is affiliated with the University of Kurdistan and has established a recognized research profile in Physics and Astronomy. His Scopus author record indicates extensive publication activity supported by a substantial citation count and a strong h-index. These indicators suggest sustained scholarly engagement and consistent contributions to scientific literature over an extended academic period. The breadth of documented work reflects active participation in advancing theoretical and analytical research within his field.[1]

Research Contributions

Karami’s research contributions are associated with theoretical investigations that support understanding of complex physical phenomena and cosmological frameworks. His scholarly work has contributed to ongoing discussions within astrophysics, gravitational theory, and related scientific disciplines. Through peer-reviewed publications, he has participated in the development of models, analytical interpretations, and theoretical perspectives that assist researchers in addressing fundamental scientific questions and evaluating emerging concepts in modern physics.[2][3]

Publications

The publication record associated with the researcher demonstrates a sustained commitment to scientific communication and peer-reviewed scholarship. With more than one hundred indexed documents, the body of work reflects consistency in research dissemination and engagement with internationally recognized journals. The publication portfolio contributes to knowledge generation and supports scholarly dialogue across multiple areas of Physics and Astronomy.[1]

  • Peer-reviewed journal articles.
  • Theoretical and analytical physics studies.
  • Collaborative international research publications.
  • High-impact scholarly contributions.

Research Impact

Research impact can be evaluated through citations, scholarly influence, and visibility within academic literature. The documented citation record associated with Karami indicates that his work has been referenced extensively by researchers working in related scientific domains. Such citation performance reflects relevance, accessibility, and contribution to ongoing investigations. Combined with a notable h-index, these indicators suggest meaningful influence on contemporary research activities and scientific knowledge development.[1][4]

Award Suitability

Evaluation for the Best Researcher Award typically considers research productivity, citation impact, publication quality, academic leadership, and contributions to scientific advancement. The available scholarly indicators associated with Kayoomars Karami demonstrate alignment with these evaluation criteria. His publication record, citation performance, recognized author profile, and sustained research activity collectively support suitability for recognition within the International Research Excellence and Best Paper Awards framework.[1][5]

Conclusion

Kayoomars Karami’s scholarly achievements reflect a productive and influential academic career within Physics and Astronomy. His extensive publication record, strong citation metrics, and measurable research impact demonstrate sustained commitment to scientific inquiry and knowledge advancement. These accomplishments provide a strong foundation for consideration under the Best Researcher Award and illustrate the significance of his contributions to contemporary scientific research and academic excellence.[1]

References

  1. Elsevier. (n.d.). Scopus author details: Kayoomars Karami, Author ID 22979495000. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=22979495000
  2. Hana Heidarian, Milad Solbi, Soma Heydari, Kayoomars Karami (2025), M. α-attractor inflation modified by GUP in light of ACT observations.
    https://doi.org/10.1016/j.physletb.2025.139833
  3. Journal of Cosmology and Astroparticle Physics. Primordial black holes in SB SUSY Gauss-Bonnet inflation.
    https://doi.org/10.1088/1475-7516/2025/01/025
  4. Springer. (2024). Primordial black holes in non-minimal Gauss–Bonnet inflation in light of the PTA data.
    https://doi.org/10.1140/epjc/s10052-024-13271-x
  5. International Research Excellence and Best Paper Awards. (n.d.). Award evaluation framework and recognition criteria.
    https://bestpaperawards.com/

Zanyar Ebrahimi | Physics and Astronomy | Best Paper Award

Best Paper Award

Structure formation in a non-canonical scalar field model of clustering dark energy
Zanyar Ebrahimi
Affiliation Research Institute For Astronomy & Astrophysics Of Maragha
Country Iran
Article Title Structure formation in a non-canonical scalar field model of clustering dark energy
Scopus ID 55759620100
Article Type Research Article
Subject Area Physics and Astronomy
Reference Count 105
Award Category Best Paper Award
Event International Research Excellence and Best Paper Awards
ORCID 0000-0003-2548-2678

The Best Paper Award recognizes the scholarly contribution of Zanyar Ebrahimi for the article titled Structure formation in a non-canonical scalar field model of clustering dark energy. Published within the field of Physics and Astronomy in 2026, the study investigates theoretical aspects of cosmic structure formation under alternative dark energy frameworks. The research contributes to ongoing discussions regarding cosmological evolution, matter clustering, and scalar field dynamics while demonstrating methodological rigor and scientific relevance.[1]

Abstract

This award-winning research examines the formation and evolution of cosmic structures within a non-canonical scalar field framework describing clustering dark energy. The study explores how modifications to conventional dark energy assumptions influence the growth of density perturbations and large-scale matter distributions throughout cosmic history. Through theoretical modeling and cosmological analysis, the work evaluates the compatibility of alternative scalar field dynamics with observed structure formation patterns. The findings provide valuable insight into dark energy behavior, the evolution of gravitational instabilities, and the broader understanding of cosmological expansion, contributing to contemporary investigations of the universe’s large-scale structure and theoretical cosmology.[2]

Keywords

Dark Energy, Scalar Field Cosmology, Structure Formation, Clustering Dark Energy, Cosmological Perturbations, Theoretical Astrophysics, Large Scale Structure, Physics and Astronomy.

Introduction

Dark energy remains one of the most significant unresolved questions in modern cosmology. Understanding how it influences the growth of galaxies, clusters, and large-scale structures is essential for explaining the universe’s accelerated expansion. Alternative scalar field models offer theoretical possibilities beyond standard cosmological assumptions and continue to attract scientific interest.[3]

Research Profile

Zanyar Ebrahimi is affiliated with the Research Institute For Astronomy & Astrophysics Of Maragha and has contributed to studies in cosmology, astrophysics, and theoretical physics. The recognized article reflects a research focus on dark energy dynamics, cosmological perturbation theory, and mechanisms governing structure formation in the evolving universe.[1]

Scientific Background

Conventional cosmological models often represent dark energy as a cosmological constant. However, scalar field approaches introduce dynamic properties that may better explain observational phenomena. Non-canonical scalar fields modify kinetic terms and can alter the behavior of perturbations, thereby affecting matter clustering and the development of large-scale cosmic structures over time.[4]

Methodology

The research employs theoretical cosmological modeling, perturbation analysis, and comparative evaluation of scalar field dynamics. Mathematical formulations are used to investigate clustering behavior and structure growth under non-canonical conditions. Predictions generated by the model are examined against accepted cosmological principles to assess consistency and scientific relevance.[2]

Key Findings

The study indicates that non-canonical scalar field models can influence matter perturbation growth and produce distinctive clustering characteristics. Results suggest that dark energy dynamics may play a more active role in structure formation than traditionally assumed. These outcomes provide additional theoretical pathways for interpreting observations related to cosmic expansion and matter distribution.[2]

Scientific Contributions

This research contributes to theoretical astrophysics by extending investigations into alternative dark energy models and their cosmological implications. The work enhances understanding of clustering dark energy, supports the development of advanced cosmological frameworks, and offers valuable perspectives for future observational and theoretical studies in large-scale structure formation.[5]

Conclusion

The Best Paper Award acknowledges a significant scholarly contribution to the study of cosmological structure formation and dark energy theory. By examining non-canonical scalar field dynamics within a clustering dark energy framework, the research expands theoretical understanding and encourages further exploration of fundamental mechanisms shaping the evolution of the universe.[2]

References

  1. Elsevier. (2026). Structure formation in a non-canonical scalar field model of clustering dark energy. Journal of High Energy Astrophysics.
    https://doi.org/10.1016/j.jheap.2025.100496
  2. ScienceDirect. (2026). Journal of High Energy Astrophysics – Research Publication Record.
    https://www.sciencedirect.com/journal/journal-of-high-energy-astrophysics
  3. General Relativity and Quantum Cosmology. (2025). Structure formation in a non-canonical scalar field model of clustering dark energy.
    https://doi.org/10.48550/arXiv.2510.16589
  4. International Research Excellence and Best Paper Awards. (2026). Best Paper Award Recognition Program.
    https://bestpaperawards.com/
  5. Elsevier. (n.d.). Scopus author details: Zanyar Ebrahimi, Author ID 55759620100. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=55759620100

Pradeep Kumar | Pharmacology, Toxicology and Pharmaceutical Science | Best Paper Award

Best Paper Award

Insights into the Biological Activities and Substituent Effects of Pyrrole Derivatives: The Chemistry-Biology Connection.
Pradeep Kumar
Affiliation KLE College of Pharmacy, Hubli
Country India
Article Title Insights into the Biological Activities and Substituent Effects of Pyrrole Derivatives: The Chemistry-Biology Connection
Scopus ID 57206689423
Article Type Review Article
Article Views 713
Reference Count 105
Award Category Best Paper Award
Event International Research Excellence and Best Paper Awards
ORCID 0000-0003-4033-8877

Pradeep Kumar, affiliated with KLE College of Pharmacy, Hubli, India, has been recognized under the Best Paper Award category for the scholarly article titled Insights into the Biological Activities and Substituent Effects of Pyrrole Derivatives: The Chemistry-Biology Connection. Published in 2024 through Wiley Online Library, the article presents a comprehensive review of pyrrole derivatives, emphasizing their pharmacological relevance, structure–activity relationships, and the influence of chemical substituents on biological performance. The work contributes to medicinal chemistry by integrating chemical and biological perspectives into a unified scientific framework.[1]

Abstract

This review article examines the chemistry and biological significance of pyrrole derivatives, a class of heterocyclic compounds widely investigated in medicinal chemistry. The study discusses structural modifications, substituent effects, and their influence on pharmacological properties including antimicrobial, anticancer, anti-inflammatory, antioxidant, and antiviral activities. Particular attention is given to structure–activity relationships that guide the rational design of bioactive molecules. By consolidating findings from diverse studies, the review highlights emerging trends, therapeutic opportunities, and future directions for pyrrole-based drug discovery. The article serves as a valuable scientific resource for researchers exploring innovative medicinal applications of pyrrole-containing compounds.[2]

Keywords

Pyrrole derivatives; Medicinal chemistry; Structure–activity relationship; Drug discovery; Heterocyclic compounds; Biological activity; Substituent effects; Pharmacological properties.

Introduction

Pyrrole derivatives occupy an important position in pharmaceutical and medicinal chemistry because of their presence in numerous natural products, therapeutic agents, and biologically active molecules. Understanding how chemical modifications affect biological activity remains essential for designing safer and more effective drug candidates. The reviewed article addresses this challenge by examining the relationship between molecular structure and pharmacological performance across diverse pyrrole-based compounds.[2]

Research Profile

Pradeep Kumar is associated with KLE College of Pharmacy, Hubli, India. His academic interests include medicinal chemistry, pharmaceutical sciences, heterocyclic chemistry, and bioactive molecular design. Through scholarly publications and scientific investigations, he has contributed to advancing knowledge regarding the therapeutic potential of chemically modified compounds and their applications in modern drug development.[1]

Scientific Background

Heterocyclic compounds constitute a significant proportion of approved pharmaceuticals. Pyrrole-containing molecules are especially important because their electronic properties and structural flexibility facilitate interactions with biological targets. Previous research has demonstrated that subtle substituent changes can significantly alter potency, selectivity, and pharmacokinetic characteristics. Consequently, comprehensive evaluations of substituent effects are essential for understanding molecular behavior and optimizing therapeutic outcomes.[3]

Methodology

The article adopts a systematic review-based methodology by collecting, analyzing, and synthesizing published scientific literature related to pyrrole derivatives. Research findings from medicinal chemistry, pharmacology, and drug discovery studies were comparatively evaluated to identify recurring structure–activity relationships. The approach enables comprehensive assessment of biological activities while providing an integrated understanding of how molecular substitutions influence pharmacological responses.[2]

Key Findings

The review demonstrates that biological activity in pyrrole derivatives is strongly influenced by substituent type, position, and electronic characteristics. Specific structural modifications were associated with improved antimicrobial, anticancer, antioxidant, and anti-inflammatory effects. The study further identifies molecular patterns that may enhance target specificity and therapeutic efficacy. These observations provide valuable guidance for future medicinal chemistry programs seeking optimized pyrrole-based drug candidates.[2]

Scientific Contributions

A major contribution of this article is the consolidation of extensive evidence regarding pyrrole derivative bioactivity into a single scholarly resource. The review provides a structured interpretation of substituent effects, facilitating better understanding of molecular design strategies. Its interdisciplinary perspective bridges chemistry and biology, supporting researchers involved in drug discovery, pharmacological evaluation, and rational therapeutic development.[4]

Conclusion

The recognized article provides a comprehensive examination of pyrrole derivatives and their diverse biological activities. By highlighting the influence of structural modifications on pharmacological behavior, the study contributes meaningful insights to medicinal chemistry research. Its synthesis of current scientific knowledge offers practical guidance for future investigations aimed at developing effective pyrrole-based therapeutic agents and expanding the understanding of chemistry–biology relationships.[5]

References

  1. Elsevier. (n.d.). Scopus author details: Pradeep Kumar, Author ID 57206689423. Scopus.
    https://www.scopus.com/authid/detail.uri?authorId=57206689423
  2. Kumar, P. (2024). Insights into the Biological Activities and Substituent Effects of Pyrrole Derivatives: The Chemistry-Biology Connection. Chemistry & Biodiversity.
    DOI: https://doi.org/10.1002/cbdv.202400534
  3. Wiley Online Library. (2024). Article abstract and publication information.
    https://onlinelibrary.wiley.com/doi/abs/10.1002/cbdv.202400534
  4. Wiley Online Library. (2024). Chemistry & Biodiversity Journal.
    https://onlinelibrary.wiley.com/journal/16121880/
  5. International Research Excellence and Best Paper Awards. (2026). Best Paper Award Recognition Program.
    https://bestpaperawards.com/

Douâae Ou-Yahia | Immunology and Microbiology | Editorial Board Member

Dr. Douâae Ou-Yahia | Immunology and Microbiology | Editorial Board Member 

Chercheur associé | Sidi Mohamed Ben Abdellah University | Morocco

Douâae Ou-Yahia is a researcher whose work primarily focuses on the bioactive properties and pharmacological potential of plant-derived compounds, particularly essential oils and polyphenols from Moroccan flora. Her research encompasses the evaluation of antioxidant, antimicrobial, cytotoxic, and genotoxic effects of various plant extracts, with a strong emphasis on discovering novel therapeutic agents, especially against breast cancer. In 2023, she co-authored several notable studies, including investigations into Ptychotis verticillata essential oil, demonstrating its antioxidant activity and potential as a breast cancer therapeutic, and studies on Mentha piperita, exploring how irrigation water quality affects its chemical profile and secondary metabolites, with implications for pharmacological applications. She has also extensively studied carob (Ceratonia siliqua var. Rahma) leaves, analyzing their polyphenol content, antimicrobial activity, cytotoxicity against cancer cell lines, and genotoxicity, highlighting their multi-faceted potential as functional bioactive compounds. Her research combines both in vitro and in silico approaches, integrating analytical profiling, chemical characterization, and computational modeling to better understand plant bioactivity and optimize therapeutic applications. Beyond her laboratory work, Douâae Ou-Yahia contributes to advancing the scientific understanding of medicinal plants in Morocco, providing insights that may support the development of natural and effective treatments. Her publications, appearing in journals such as Life, International Journal of Plant Biology, Pharmaceuticals, and Antibiotics, reflect a commitment to rigorous experimental design and multidisciplinary collaboration with other experts in the fields of pharmacology, chemistry, and plant biology. Overall, her work bridges fundamental phytochemical research and applied biomedical science, offering promising avenues for natural product-based therapies and contributing to global efforts in exploring sustainable, plant-based solutions for healthcare challenges.

Profile: ORCID

Featured Publications

  1. Taibi, M., Elbouzidi, A., Ouahhoud, S., Loukili, E. H., Ou-Yahia, D., Ouahabi, S., Alqahtani, A. S., Noman, O. M., Addi, M., Bellaouchi, R., et al. (2023). Evaluation of antioxidant activity, cytotoxicity, and genotoxicity of Ptychotis verticillata essential oil: Towards novel breast cancer therapeutics. Life, 13(7), 1586.

  2. Haddou, M., Taibi, M., Elbouzidi, A., Loukili, E. H., Yahyaoui, M. I., Ou-Yahia, D., Mehane, L., Addi, M., Asehraou, A., Chaabane, K., et al. (2023). Investigating the impact of irrigation water quality on secondary metabolites and chemical profile of Mentha piperita essential oil: Analytical profiling, characterization, and potential pharmacological applications. International Journal of Plant Biology, 14(3), 49.

  3. Elbouzidi, A., Taibi, M., Ouassou, H., Ouahhoud, S., Ou-Yahia, D., Loukili, E. H., Aherkou, M., Mansouri, F., Bencheikh, N., Laaraj, S., et al. (2023). Exploring the multi-faceted potential of carob (Ceratonia siliqua var. Rahma) leaves from Morocco: A comprehensive analysis of polyphenols profile, antimicrobial activity, cytotoxicity against breast cancer cell lines, and genotoxicity. Pharmaceuticals, 16(6), 840.

  4. Taibi, M., Elbouzidi, A., Ou-Yahia, D., Dalli, M., Bellaouchi, R., Tikent, A., Roubi, M., Gseyra, N., Asehraou, A., Hano, C., et al. (2023). Assessment of the antioxidant and antimicrobial potential of Ptychotis verticillata Duby essential oil from Eastern Morocco: An in vitro and in silico analysis. Antibiotics, 12(4), 655.

  5. Elbouzidi, A., Taibi, M., Ou-Yahia, D., Loukili, E. H., & others. (2023). Exploring the multi-faceted potential of carob leaves from Morocco: A comprehensive analysis of polyphenols profile, antimicrobial activity, cytotoxicity against breast cancer cell lines, and genotoxicity. Preprint.

Douâae Ou-Yahia’s research advances the understanding of bioactive compounds from Moroccan plants, providing novel insights into natural antioxidants, antimicrobials, and cancer therapeutics. Her work bridges fundamental phytochemistry and applied biomedical science, contributing to healthcare innovation and sustainable, plant-based solutions with global impact.