William Mills III | Translational Neuroscience | Best Researcher Award

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Dr. William Mills III | Translational Neuroscience | Best Researcher Award

Dr. William Mills III, University of Virginia, United States.

William A. Mills III, known as Tré, is a dedicated neuroscientist whose academic and professional journey reflects a strong commitment to translational and interdisciplinary research. With foundational training from Virginia Tech and international exposure through studies in China, Tré has developed a deep expertise in neurovascular coupling and glial biology. His doctoral and postdoctoral research has significantly advanced our understanding of how microglia and aging influence the brain’s vascular systems. Through prestigious fellowships and awards, including the NIH K99/R00 and the AHA Postdoctoral Fellowship, Tré has proven his potential to become a leading figure in neuroscience. His work bridges multiple scientific disciplines and focuses on uncovering mechanisms that contribute to neurological aging and disease.

Profile

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🎓 Early Academic Pursuits

William A. Mills III, fondly known as Tré, laid a solid foundation for his scientific career through rigorous and diverse academic training. He earned his Bachelor of Science degree in Biological Sciences from Virginia Tech in 2014, where he was actively involved in research labs focusing on virology, behavioral ecology, and disease ecology. His passion for cross-cultural and interdisciplinary learning was evident as he pursued Chinese language studies at Xi’an Jiaotong-Liverpool University from 2014 to 2015. This global academic exposure was followed by his Ph.D. in Translational Biology, Medicine & Health with a neuroscience focus at Virginia Tech (2015–2021), where he developed a strong interest in neurovascular and glial biology. These formative experiences created a well-rounded and curious scientist ready to tackle complex biomedical questions.

🧠 Professional Endeavors in Neuroscience

Tré’s professional journey took a pivotal turn when he joined the Eyo Lab at the University of Virginia as a Postdoctoral Research Fellow in 2021. His research investigates the intricate role of microglia in regulating capillary basal tone and neurovascular coupling—an area that sits at the intersection of neuroimmunology and vascular biology. His graduate years in the Sontheimer Lab had already shaped his expertise in glial signaling pathways, particularly focusing on the effects of aging on gliovascular interactions involving EGFR and pSTAT3. These experiences underscore a continuous commitment to understanding the cellular mechanisms that underpin brain function and disease.

🧪 Contributions and Research Focus

Throughout his research career, Tré has contributed significantly to the field of neurovascular biology and glial cell research. His scientific curiosity has spanned from studying the cellular mechanics of viral encapsidation in early projects to evaluating semaphorin roles in cardiovascular pathology. Notably, his doctoral work on gliovascular plasticity and his current postdoctoral focus on microglia’s role in cerebral blood flow regulation highlight his interdisciplinary approach. By bridging neuroscience, immunology, and vascular biology, he is shedding light on the fundamental processes that maintain brain health and how their disruption leads to age-related and neurodegenerative diseases.

🏅 Accolades and Recognition

Tré’s outstanding research potential has been recognized by several prestigious institutions. He was awarded the American Heart Association Career Development Award (which he respectfully declined), the American Heart Association Postdoctoral Fellowship (25POST1376070), and the UVA Brain Institute Postdoctoral Research Fellowship. In addition, he secured training support through the UVA Cardiovascular Research Center T32 Training Grant, reflecting the strong institutional belief in his capabilities. Most notably, he earned the competitive NIH K99/R00 Pathway to Independence Award, a mark of distinction for early-career researchers poised to transition to faculty positions.

🔬 Impact and Influence in Translational Neuroscience

Tré’s research contributions are highly translational in nature, linking basic cellular mechanisms to potential therapeutic implications in aging, stroke, and neurodegeneration. His work on microglial function in neurovascular coupling could provide new insights into how blood flow dysregulation contributes to cognitive decline and dementia. By exploring how aging alters glial and vascular interactions, Tré’s research holds the promise to inform interventions targeting the brain’s support systems to preserve function in aging populations. His influence is also visible through collaborative projects, lab mentorship, and participation in international research endeavors.

🌍 Legacy and Future Contributions

Looking ahead, Tré is poised to leave a lasting legacy in the field of neurovascular biology. With a trajectory marked by intellectual rigor, global awareness, and translational relevance, he is expected to lead pioneering studies that will redefine our understanding of brain support systems in health and disease. The foundation laid by his NIH K99/R00 award positions him well to establish an independent research program, where he will likely mentor future scientists and push the boundaries of neuroscience through integrative and innovative research methodologies.

🧬 A Champion of Interdisciplinary Science

A defining trait of Tré’s career is his seamless integration of diverse scientific fields—ranging from immunology and neuroscience to cardiovascular biology and behavioral ecology. This interdisciplinary ethos not only enriches his research output but also positions him as a bridge-builder in science, capable of uniting different perspectives to address complex biomedical challenges. His academic journey from microbiology and animal behavior to glial biology exemplifies a dynamic scientist committed to evolving with the science, while remaining grounded in his passion for discovery.

Publication

  • Title: Capillary-associated microglia regulate vascular structure and function through PANX1-P2RY12 coupling in mice
    Authors: K. Bisht, K.A. Okojie, K. Sharma, D.H. Lentferink, Y.Y. Sun, H.R. Chen, …
    Year: 2021

 

  • Title: Spatially expandable fiber-based probes as a multifunctional deep brain interface
    Authors: S. Jiang, D.C. Patel, J. Kim, S. Yang, W.A. Mills III, Y. Zhang, K. Wang, Z. Feng, …
    Year: 2020

 

  • Title: Astrocyte plasticity in mice ensures continued endfoot coverage of cerebral blood vessels following injury and declines with age
    Authors: W.A. Mills III, A.L.M. Woo, S. Jiang, J. Martin, D. Surendran, M. Bergstresser, …
    Year: 2022

 

  • Title: Lactobacillus rescues postnatal neurobehavioral and microglial dysfunction in a model of maternal microbiome dysbiosis
    Authors: Y. Lebovitz, E.A. Kowalski, X. Wang, C. Kelly, M. Lee, V. McDonald, R. Ward, …
    Year: 2019

 

  • Title: Potassium and glutamate transport is impaired in scar-forming tumor-associated astrocytes
    Authors: S.C. Campbell, C. Muñoz-Ballester, L. Chaunsali, W.A. Mills III, J.H. Yang, …
    Year: 2020

 

  • Title: LRRTM1 underlies synaptic convergence in visual thalamus
    Authors: A. Monavarfeshani, G. Stanton, J. Van Name, K. Su, W.A. Mills III, K. Swilling, …
    Year: 2018

 

  • Title: EphA4/Tie2 crosstalk regulates leptomeningeal collateral remodeling following ischemic stroke
    Authors: B. Okyere, W.A. Mills, X. Wang, M. Chen, J. Chen, A. Hazy, Y. Qian, J.B. Matson, …
    Year: 2020

 

  • Title: Nano-optoelectrodes integrated with flexible multifunctional fiber probes by high-throughput scalable fabrication
    Authors: S. Jiang, J. Song, Y. Zhang, M. Nie, J. Kim, A.L. Marcano, K. Kadlec, …
    Year: 2021

 

  • Title: The emergence of the calvarial hematopoietic niche in health and disease
    Authors: W.A. Mills III, M.A. Coburn, U.B. Eyo
    Year: 2022

 

  • Title: Using zebrafish to elucidate glial-vascular interactions during CNS development
    Authors: R.A. Umans, C. Pollock, W.A. Mills III, K.C. Clark, Y.A. Pan, H. Sontheimer
    Year: 2021

 

🧾 Conclusion

Tré stands out as a forward-thinking and highly skilled researcher whose contributions are shaping the future of neurovascular and glial research. His innovative approach, academic excellence, and recognition by top funding agencies underscore his suitability for leadership roles in neuroscience. As he transitions into an independent research career, Tré is expected to make enduring impacts on the scientific community through groundbreaking discoveries, mentorship, and interdisciplinary collaboration. His trajectory is a testament to his dedication, curiosity, and potential to transform brain health research.

Hongrui Meng | Neurodegenerative disease | Excellence in Research Award

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Prof. Dr. Hongrui Meng | Neurodegenerative disease | Excellence in Research Award

Prof. Dr. Hongrui Meng,  Institute of Neuroscience, Soochow University, China.

Dr. Hongrui Meng is a highly accomplished neuroscientist whose academic path began with a Ph.D. in Behavioural Neuroscience from Hamamatsu University School of Medicine in Japan. He later conducted postdoctoral research in molecular neurobiology and human genetics at Juntendo University, Tokyo. Currently a professor at the Institute of Neuroscience, Soochow University, Dr. Meng leads a research team dedicated to uncovering the molecular and mitochondrial mechanisms underlying Parkinson’s disease and ALS. His work spans high-impact research projects funded by JSPS, NSFC, and other prestigious bodies. In addition to numerous scientific publications, he has contributed to diagnostic innovation through patented miRNA detection methods. His influence extends beyond academia through translational applications such as wearable technologies for Parkinson’s symptom monitoring.

Profile

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🎓 Early Academic Pursuits

Dr. Hongrui Meng began his distinguished academic journey in the field of neuroscience by earning his Ph.D. in Behavioural Neuroscience from the prestigious Hamamatsu University School of Medicine in Japan. His early education and training laid a strong foundation in experimental neuroscience, with a focus on the behavioral manifestations of neurodegenerative conditions. These formative years not only sharpened his scientific curiosity but also equipped him with the cross-disciplinary expertise to address complex neurological questions.

🧠 Professional Endeavors

Following his doctoral studies, Dr. Meng advanced his specialization through postdoctoral training in molecular neurobiology and human genetics at Juntendo University in Tokyo. There, he immersed himself in high-level research focusing on the genetic underpinnings of neurological disorders. His competence and dedication soon earned him a faculty appointment as an Assistant Professor in the Department of Research for Neurodegenerative Diseases and Dementia. His professional arc reached a significant milestone in 2020 when he was promoted to Full Professor and moved to the Institute of Neuroscience at Soochow University, where he now leads the Laboratory of Molecular Neurology.

🧬 Contributions and Research Focus

Dr. Meng’s scientific contributions center on the molecular mechanisms of Parkinson’s disease and amyotrophic lateral sclerosis (ALS). His research bridges mitochondrial dysfunction, alpha-synuclein aggregation, and neurodegeneration. He has completed pivotal studies supported by the Japan Society for the Promotion of Science and the Takeda Pharmaceutical Foundation, delving into the role of CHCHD2 gene mutations and mitochondrial pathways. His ongoing projects funded by the National Natural Science Foundation of China (NSFC) explore mitochondrial unfolded protein responses (mtUPR), while another innovative project in Suzhou focuses on wearable technology for monitoring Parkinson’s disease symptoms—demonstrating his commitment to translational and patient-centered neuroscience.

🔬 Innovation and Scientific Output

A notable innovator, Dr. Meng has made strides in molecular diagnostic technologies. His work has led to the development of high-throughput RT-qPCR-based methods for detecting primary and precursor miRNAs, contributing to enhanced genetic analysis of neurodegenerative disorders. He holds a patent granted in South Africa and another under process in China, underscoring his role at the intersection of research and technology. Furthermore, his publications in highly regarded journals like Current Issues in Molecular Biology and Cell Communication and Signaling reflect a consistent record of impactful findings that inform both fundamental neuroscience and clinical approaches.

🏅 Accolades and Recognition

Dr. Meng’s ascent in the academic community has been marked by numerous grants, including multiple from the JSPS and NSFC, attesting to the trust placed in his research vision by top funding bodies. While a formal list of awards may be under-documented, his rapid progression from postdoctoral fellow to professor and research team leader in less than a decade speaks volumes about his recognition among peers and institutional leadership. His leadership in multi-disciplinary and international collaborations is an implicit accolade of his scientific reliability and visionary perspective.

🌍 Impact and Influence

Through his groundbreaking work on mitochondrial mechanisms and neurodegeneration, Dr. Meng is helping to reshape current understanding of Parkinson’s disease pathophysiology. His investigations into alpha-synucleinopathy and microglial disruption have provided fresh insights into cellular degeneration and neuroimmune interactions. Beyond academia, his involvement in developing wearable diagnostic tools highlights his drive to impact patient lives directly. As a consultant on neuroprotective treatments such as PD-018/19, he bridges the academic and pharmaceutical worlds to accelerate therapeutic discovery.

🔮 Legacy and Future Contributions

Looking forward, Dr. Meng is poised to be a leading figure in neurogenetic diagnostics and therapeutic innovation. His laboratory at Soochow University serves as an incubator for future discoveries in neurodegenerative disease mechanisms, and his continued work in mitochondrial research promises to inform emerging therapies. With a growing publication record, international patents, and a robust research pipeline, Dr. Meng’s legacy will be one of bridging basic neuroscience with clinical application—paving the way for novel interventions and a better understanding of brain disorders in the molecular era.

Publication

 

  • Title: Dicer Is Involved in Cytotoxicity and Motor Impairment Induced by TBPH Deficiency
    Authors: Xiang Long, Yijie Wang, Hongrui Meng
    Year: 2025

 

  • Title: Transcriptomic analysis of lipid metabolism genes in Alzheimer’s disease: highlighting pathological outcomes and compartmentalized immune status
    Authors: Sun Y., Zhang Y., Jiang M., Long X., Miao Y., Du H., Zhang T., Meng H., Ma X.
    Year: 2024

 

  • Title: CHCHD2 P14L, found in amyotrophic lateral sclerosis, exhibits cytoplasmic mislocalization and alters Ca2+ homeostasis
    Authors: Aya Ikeda, Hongrui Meng, Daisuke Taniguchi, Muneyo Mio, Manabu Funayama, Kenya Nishioka, Mari Yoshida, Yuanzhe Li, Hiroyo Yoshino, Tsuyoshi Inoshita et al.
    Year: 2024

 

  • Title: TDP-43 mutations-induced defects in miRNA biogenesis and cytotoxicity by differentially obstructing Dicer activity in Drosophila and in vitro
    Authors: Xiang Long, Mengni Jiang, Yongzhen Miao, Huanhuan Du, Ting Zhang, Zhuoya Ma, Jiao Li, Chunfeng Liu, Hongrui Meng
    Year: 2024

 

  • Title: A Simple Technique to Assay Locomotor Activity in Drosophila
    Authors: Long X., Du H., Jiang M., Meng H.
    Year: 2023

 

  • Title: Functional MHCI deficiency induces ADHD-like symptoms with increased dopamine D1 receptor expression
    Authors: Meng H.-R., Suenaga T., Edamura M., Nakahara D., Murakami G., Fukuda A., Ishida Y.
    Year: 2021

 

  • Title: Light-driven activation of mitochondrial proton-motive force improves motor behaviors in a Drosophila model of Parkinson’s disease
    Authors: Imai Y., Hattori N., Inoshita T., Shiba-Fukushima K., Meng H., Hara K.Y., Sawamura N.
    Year: 2019

 

  • Title: Mutations in CHCHD2 cause α-synuclein aggregation
    Authors: Ikeda A., Nishioka K., Takanashi M., Li Y., Mori A., Okuzumi A., Izawa N., Ishikawa K.-I., Funayama M., Imai Y. et al.
    Year: 2019

 

  • Title: Parkinson’s disease-associated iPLA2-VIA/PLA2G6 regulates neuronal functions and α-synuclein stability through membrane remodeling
    Authors: Mori A., Hatano T., Koinuma T., Kubo S.-I., Spratt S., Yamashita C., Okuzumi A., Imai Y., Hattori N., Inoshita T. et al.
    Year: 2019

 

  • Title: Twin CHCH proteins, CHCHD2, and CHCHD10: Key molecules of Parkinson’s disease, amyotrophic lateral sclerosis, and frontotemporal dementia
    Authors: Imai Y., Hattori N., Meng H., Shiba-Fukushima K.
    Year: 2019

 

🧾 Conclusion

Dr. Hongrui Meng’s career reflects a dynamic blend of academic excellence, molecular research innovation, and translational neuroscience. His scientific endeavors have not only enriched the understanding of neurodegenerative diseases but have also paved the way for novel diagnostic and therapeutic strategies. With a growing portfolio of impactful research, patents, and leadership in neurobiology, Dr. Meng stands out as a driving force in the global fight against neurological disorders. His work promises continued contributions to neuroscience with lasting influence on both scientific knowledge and patient care.

 

Joice Margareth de Almeida Rodolpho | Molecular Neuroscience | Best Researcher Award

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Mrs. Joice Margareth de Almeida Rodolpho | Molecular Neuroscience | Best Researcher Award

Mrs. Joice Margareth de Almeida Rodolpho, Universidade Federal de São Carlos, Brazil.

Joice Margareth de Almeida Rodolpho is a dedicated Brazilian researcher with a strong foundation in biotechnology, parasitology, immunology, and molecular biology. She earned her Master’s and Ph.D. from the Federal University of São Carlos (UFSCar), where she explored the role of eosinophils as antigen-presenting cells in parasitic infections like Toxocara canis and Schistosoma mansoni. Her work is recognized for integrating experimental immunology with therapeutic innovations, such as the evaluation of natural plant extracts and nanomaterials for infection control. She further specialized in Flow Cytometry and Oncohematology, enhancing her analytical capabilities. With multiple awards and citations, her impactful contributions continue to strengthen Brazil’s standing in parasitological and immunological research.

Profile

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🎓 Early Academic Pursuits

Joice Margareth de Almeida Rodolpho began her academic journey in Brazil, developing a strong foundation in the life sciences. Her early interest in molecular biology and parasitology led her to pursue advanced studies at the esteemed Universidade Federal de São Carlos (UFSCar). She earned her Master’s degree in Biotechnology between 2009 and 2012, conducting significant research on Toxocara canis, particularly on the phenotypic characterization of eosinophils as antigen-presenting cells. This early work not only revealed her meticulous scientific inquiry but also laid the groundwork for her deeper exploration into immunology.

🧬 Professional Endeavors in Molecular and Evolutionary Genetics

Driven by a passion for understanding immune responses, Joice pursued a Ph.D. in Evolutionary Genetics and Molecular Biology at UFSCar from 2013 to 2017. Her doctoral research focused on the role of eosinophils as antigen-presenting cells both in vitro and ex vivo, offering vital insights into host-parasite interactions and immune regulation. Her work during this period was supported by a prestigious FAPESP scholarship, demonstrating her academic excellence and the relevance of her contributions. Under the mentorship of Professor Fernanda de Freitas Anibal, Joice refined her skills in experimental immunology and cellular biology.

🧪 Contributions and Research Focus in Parasitology and Immunopathology

Joice Rodolpho’s primary research interests lie at the intersection of parasitology, cellular immunology, and experimental pathology. Her studies explore how parasitic infections, such as those caused by Schistosoma mansoni and Toxocara canis, affect immune cell function, especially eosinophils. She has also contributed to investigations into natural plant extracts, like Mentha piperita L., assessing their therapeutic potential in modulating parasitic infections. Moreover, she extended her expertise to the field of nanomaterials, evaluating the cytotoxicity and cell death mechanisms induced by compounds like Ag₂WO₄, thus bridging classical parasitology with emerging biomedical technologies.

🏅 Accolades and Recognition in Scientific Circles

Throughout her career, Joice has received several recognitions that reflect the impact and originality of her research. In 2010, she was honored with a Menção Honrosa (Honorable Mention) for her work on Mentha piperita L. in treating Schistosoma mansoni, earning 2nd place in diagnostics and treatment. She continued to gain academic acclaim with awards at major conferences, including the VI Congresso da Sociedade Paulista de Parasitologia (2012) and the XXII B-MRS Meeting in 2024, highlighting her work on cytotoxic responses and innovative parasitological control methods. In 2024, her project on the parasitological and pathological evaluation of AW-HRL-C for schistosomiasis control was notably recognized by UNIFESP.

🧠 Impact and Influence in Experimental Immunology

Joice’s dedication to experimental immunology and cytometry has allowed her to mentor and influence upcoming researchers, especially in specialized fields such as flow cytometry. Her recent specialization in Immunology and Oncohematology by Flow Cytometry (2021–2022) at IPESSP further enriched her profile, showcasing her commitment to continuous learning and application of advanced technologies in immune profiling. Her ability to merge classical immunopathology with state-of-the-art cytometric tools reflects her versatility and forward-thinking scientific approach.

🌱 Legacy and Future Contributions in Biomedical Science

Poised to make lasting contributions, Joice Margareth de Almeida Rodolpho stands at the forefront of research into host-pathogen interactions, parasitic disease management, and immune cell function modulation. Her unique interdisciplinary approach—integrating molecular biology, natural product pharmacology, and immunological techniques—positions her as a valuable contributor to both academic research and potential therapeutic advancements. She is expected to lead innovative research in the treatment of neglected tropical diseases and immunological disorders, with implications for global health.

🔬 Research Field Relevance and Scientific Identity

As a scholar deeply embedded in the Brazilian scientific ecosystem, Joice’s identity is reflected in her multiple citation forms, indicating her widespread academic collaborations and international visibility. Her expertise bridges evolutionary genetics, biotechnology, cytometry, and immunoparasitology—making her a multifaceted researcher. Her contributions are cited under various names such as “RODOLPHO, JOICE M. A.” and “Joice Margareth de Almeida Rodolpho,” reflecting a robust presence in scholarly literature and ensuring her work continues to guide parasitological and immunological research for years to come.

Publication

  • Title: Biomarkers and Mental Disorders: A Relevance Analysis Using a Random Forest Algorithm
    Authors: Joice M. A. Rodolpho; Krissia F. Godoy; Bruna D. L. Fragelli; Jaqueline Bianchi; et al.
    Year: 2025

 

  • Title: Death Risk Score Model of Hospitalized COVID‐19 Patients: A Cohort Study
    Authors: Gustavo A. Cruz; Thais B. Boteon; Henrique Pott; Joice M. A. Rodolpho; et al.
    Year: 2025

 

  • Title: Synergistic Antifungal Effect and In Vivo Toxicity of a Monoterpene Isoespintanol Obtained from Oxandra xylopioides Diels
    Authors: Orfa I. C. Martínez; Alberto Angulo; Joice Rodolpho; Krissia F. Godoy; et al.
    Year: 2024

 

  • Title: Synergistic Antifungal Effect and In Vivo Toxicity of the Monoterpene Isoespintanol Obtained from Oxandra xylopioides Diels (Preprint)
    Authors: Orfa I. C. Martínez; Alberto Angulo; Joice M. A. Rodolpho; et al.
    Year: 2024

 

  • Title: Carbon Black CB-EDA Nanoparticles in Macrophages: Changes in the Oxidative Stress Pathway and in Apoptosis Signaling
    Authors: Joice M. A. Rodolpho; Krissia F. Godoy; Bruna D. L. Fragelli; et al.
    Year: 2023

 

  • Title: HGPRT and PNP: Recombinant Enzymes from Schistosoma mansoni and Their Role in Immunotherapy during Experimental Murine Schistosomiasis
    Authors: Bruna D. L. Fragelli; Ana C. Fattori; Joice M. A. Rodolpho; et al.
    Year: 2023

 

  • Title: Titanium Dioxide Nanoparticle (TiO2 NP) Induces Toxic Effects on LA-9 Mouse Fibroblast Cell Line
    Authors: Ana C. M. Fattori; Patricia Brassolatti; Joice M. A. Rodolpho; et al.
    Year: 2023

 

  • Title: Analysis of Cytotoxicity and Genotoxicity in a Short-Term Dependent Manner Induced by a New Titanium Dioxide Nanoparticle in Murine Fibroblast Cells
    Authors: Pedrino, M.; Brassolatti, P.; Joice M. A. Rodolpho; et al.
    Year: 2022

 

  • Title: Functionalized Titanium Nanoparticles Induce Oxidative Stress and Cell Death in Human Skin Cells
    Authors: Brassolatti, P.; Joice M. A. Rodolpho; Krissia F. Godoy; et al.
    Year: 2022

 

  • Title: Toxicological Effects of the Mixed Iron Oxide Nanoparticle (Fe₃O₄ NP) on Murine Fibroblasts LA-9
    Authors: Alves Feitosa, K.; Joice M. A. Rodolpho; et al.
    Year: 2022

 

🧾 Conclusion

Joice Rodolpho’s academic journey and scientific contributions reveal a researcher of high caliber, committed to advancing our understanding of host-pathogen dynamics and immune system function. Her work, grounded in rigorous experimentation and innovation, holds promise for developing novel therapies for neglected tropical diseases. With a forward-looking approach and interdisciplinary expertise, she stands out as a key contributor in biomedical science, poised to influence future discoveries in immunopathology and disease control.