Dr. Emanuele Calabrò | Effects of electromagnetic fields on biological systems | Best Researcher Award 

MIUR - University of Messina | Italy 

AUTHOR PROFILE

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• ORCID

EARLY ACADEMIC PURSUITS

Dr. Emanuele Calabrò embarked on his academic journey with a Bachelor's degree in Physics from the University of Messina in 1990, followed by a Bachelor's degree in Engineering from the same institution in 1995. His early academic work laid a strong foundation in both theoretical and applied physics. He furthered his education with several post-graduate qualifications, including specialized training in areas such as stone material degradation, robotics, and energy systems and technologies. Notably, he completed a PhD course focusing on the Effects of Electromagnetic Fields on Biological Systems, which became a significant area of his research.

PROFESSIONAL ENDEAVORS

Dr. Calabrò has held various teaching and research positions throughout his career. He began as a Teaching Assistant of Topography at the University of Messina and later served as a Full Professor of Electrotechnics at the Technical Technological Institute “Sarrocchi” in Siena. His professional journey also includes roles as an Adjunct Professor at the University of Siena, where he taught Biomedical Physics and Electronic Measurements. Since 1999, Dr. Calabrò has been a Full Professor of Physics and Environmental Physics at the Technical Technological Institute “Verona Trento” in Messina. His academic career is marked by his contributions to the field of applied physics, with a particular focus on the Effects of Electromagnetic Fields on Biological Systems.

CONTRIBUTIONS AND RESEARCH FOCUS

Dr. Calabrò's research has significantly advanced the understanding of the Effects of Electromagnetic Fields on Biological Systems. His doctoral thesis investigated the impact of Extremely Low Frequencies (ELF) and Microwaves (MW) Electromagnetic Fields on cells and protein structures. This research is critical for developing guidelines and safety standards related to electromagnetic exposure. His work encompasses both theoretical models and experimental studies, providing a comprehensive understanding of how electromagnetic fields interact with biological tissues.

IMPACT AND INFLUENCE

Dr. Calabrò's research has had a profound impact on the field of applied physics, particularly in the study of electromagnetic fields and their biological effects. His findings have informed safety regulations and contributed to the broader scientific discourse on electromagnetic exposure. His work is frequently cited in academic literature, underscoring its importance and influence in the field. Dr. Calabrò's research not only advances scientific knowledge but also has practical implications for public health and safety.

ACADEMIC CITES

Dr. Calabrò's extensive body of work has been widely recognized and cited by his peers in the academic community. His research on the Effects of Electromagnetic Fields on Biological Systems has been referenced in numerous studies, highlighting the relevance and impact of his contributions. His findings have been integral to advancing the understanding of electromagnetic field interactions with biological entities, making his work a cornerstone in this area of study.

LEGACY AND FUTURE CONTRIBUTIONS

As a Full Professor of Physics, Dr. Emanuele Calabrò continues to contribute to the academic and scientific community through his teaching and research. His legacy is built on his pioneering work in understanding the Effects of Electromagnetic Fields on Biological Systems, and his future contributions are likely to further this critical area of research. By mentoring the next generation of scientists and conducting innovative research, Dr. Calabrò is poised to make lasting contributions to applied physics and public health.

EFFECTS OF ELECTROMAGNETIC FIELDS ON BIOLOGICAL SYSTEMS 

Dr. Calabrò’s distinguished career is characterized by his in-depth research on the Effects of Electromagnetic Fields on Biological Systems. This research area remains a central theme in his work, reflecting his commitment to advancing scientific understanding and informing public health practices. His expertise in this field is widely recognized, and the keywords associated with his research—Effects of Electromagnetic Fields on Biological Systems, applied physics, and environmental physics—highlight the core areas of his scholarly contributions and underscore his impact on the scientific community.

NOTABLE PUBLICATION

• Monitoring of biochemical changes provides evidence for alterations associated with employment of static magnetic fields

  Month: February    Year: 2024

• The fight between static magnetic fields and thermal molecular agitation in organic macromolecules

  Month: January   Year: 2024

• Spectroscopic detection of chromatin uncoiling and chromosome alignment in neuronal-like cells under exposure to low intensity magnetic fields

  Month: January   Year: 2024

• Effects of replacing water molecules with sodium-chloride in a typical protein in aqueous solution under exposure to microwaves

  Month: August    Year: 2021

• Competition between N–H bending vibration and α-helix polarization under 50 Hz magnetic field in SH-SY5Y neuronal-like cells

  Month: May    Year: 2020