Ahmet Murat Şenışık | Medical Physics | Best Researcher Award

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Dr. Ahmet Murat Şenışık | Medical Physics | Best Researcher Award

Altınbaş University from Turkey

Dr. Ahmet Murat Şenışık is a seasoned medical physicist with deep expertise in nuclear physics, radiotherapy, and advanced imaging techniques. With a career spanning over two decades, he has demonstrated a strong commitment to both academic excellence and clinical innovation. His multidisciplinary background—rooted in nuclear sciences, medical physics, and physics education—has positioned him at the intersection of research, teaching, and clinical practice. Currently serving as a faculty member at Altınbaş University’s Radiotherapy Program, Dr. Şenışık plays a vital role in training the next generation of radiotherapy professionals while contributing significantly to scientific research. His research interests are wide-ranging, including radiation dosimetry, nuclear medicine, theranostics, and the application of nanotechnology in oncology. He has participated in numerous national and international congresses and has co-authored more than 15 peer-reviewed publications. Additionally, Dr. Şenışık has shown strong leadership through administrative roles and educational committees, reflecting his holistic approach to academic and institutional development. His collaborative projects with international researchers further emphasize his global research footprint. As a recipient of several academic honors and an active contributor to ongoing scientific discourse, Dr. Şenışık stands out as a highly suitable candidate for the Best Researcher Award in recognition of his contributions to the advancement of radiological sciences.

Professional Profile

Education

Dr. Ahmet Murat Şenışık’s educational journey reflects a robust foundation in physics and a dedicated progression into nuclear and medical physics. He completed his undergraduate studies at Ege University, earning a Bachelor’s degree in Physics in 2000, followed by a Teaching Formation Certificate from the Faculty of Literature at the same university. He later pursued a Master’s degree in Physics at Dokuz Eylül University (2000–2003), where he delved into advanced physical concepts, including superconductivity and acoustic waves. His academic passion culminated in a PhD in Nuclear Applications from the Institute of Nuclear Sciences at Ege University in 2014. His doctoral work integrated nuclear medicine with radiopharmaceutical development, showcasing his ability to bridge theoretical knowledge with clinical applications. Continuing his specialization, Dr. Şenışık obtained a second Master’s degree in Medical Physics from Istanbul University’s Institute of Health Sciences in 2020, reflecting his commitment to staying at the forefront of clinical radiology and radiation safety. This combination of physics, nuclear sciences, and medical applications has equipped him with the comprehensive expertise required for innovative research and effective teaching in radiotherapy. His strong academic background underpins his contributions to medical physics and positions him as a leader in both clinical and academic settings.

Professional Experience

Dr. Ahmet Murat Şenışık has accumulated a diverse and dynamic portfolio of professional experiences in academic and clinical settings. He began his career as a physics teacher in 2002 before transitioning to a radiotherapy physicist role at Şifa Hospital, where he served for over a decade (2003–2015). During this period, he played a critical role in clinical treatment planning, radiation safety, and quality assurance in radiotherapy. His expertise later transitioned into academia, where he began teaching radiotherapy at Şifa University’s Health Services Vocational School. In 2016, he joined Altınbaş University’s Health Services Vocational School, initially as an instructor and later advancing to a faculty member in 2020. In this role, he is actively engaged in curriculum development, lecturing, supervising students, and conducting interdisciplinary research. Dr. Şenışık also contributes to institutional operations through various administrative responsibilities, including membership on the Examination Audit Committee, Adaptation Commission, and Pearson Accreditation body. His hands-on experience in radiotherapy clinics, combined with academic leadership, allows him to bring practical insights into the classroom. His blend of clinical, teaching, and administrative roles over the past two decades underscores his multifaceted contributions to the field of medical physics and exemplifies the qualities of a dedicated academic professional.

Research Interests

Dr. Ahmet Murat Şenışık’s research interests lie at the convergence of nuclear physics, radiopharmacy, and medical imaging, reflecting his interdisciplinary academic foundation and clinical experience. He has a strong interest in radiation dosimetry, particularly in the optimization of radiotherapy treatment plans and comparative analyses of different radiotherapy systems such as CyberKnife and Varian TrueBeam STX. His work often explores cutting-edge technologies in radiotherapy, including stereotactic body radiotherapy (SBRT), image-guided radiation therapy (IGRT), and advanced treatment planning systems like RaySearch. Dr. Şenışık is also deeply involved in the development and evaluation of radiopharmaceuticals and radiolabeled compounds for both diagnostic and therapeutic applications. His research extends into nanotechnology, with a focus on multifunctional nano-platforms for drug delivery and radiosensitization. He collaborates on interdisciplinary studies that integrate materials science, biochemistry, and oncology. Recent research also includes public health-oriented studies, such as radiation awareness surveys and the evaluation of safety protocols during the COVID-19 pandemic. Through his expansive research agenda, Dr. Şenışık aims to enhance the safety, efficacy, and personalization of cancer treatment. His curiosity and dedication to exploring the frontiers of medical physics underscore his stature as a leading researcher in radiological sciences and cancer therapy.

Research Skills

Dr. Ahmet Murat Şenışık possesses an exceptional repertoire of research skills that span theoretical modeling, laboratory experimentation, and clinical data analysis. He is highly proficient in radiation dosimetry techniques and treatment planning system evaluation, including Monte Carlo simulations—a crucial skill for accurate dose calculation and optimization in radiotherapy. His expertise extends to radiopharmaceutical synthesis and in-vivo imaging, demonstrated in his research on [18F]FDG and 99mTc(CO)3+ compounds. His skill in PET/CT dose reevaluation and organ dose calculations using MIRD formalism signifies a precise approach to nuclear medicine protocols. Dr. Şenışık is adept in designing multidisciplinary studies, working with nanocarriers like niosomes and metal-organic frameworks (MOFs) to enhance cancer therapy. His familiarity with advanced technologies such as RaySearch TPS and IGRT quality control reflects a strong command of both hardware and software in modern radiation oncology. Additionally, he demonstrates competence in statistical analysis, scientific writing, and interdisciplinary collaboration—skills evident from his co-authored publications and multinational research endeavors. His ability to translate complex scientific concepts into practical clinical applications makes him a valuable contributor to the fields of medical physics, radiology, and oncology. These competencies underline his eligibility for top-tier academic and research recognitions, including the Best Researcher Award.

Awards and Honors

Dr. Ahmet Murat Şenışık has earned significant recognition through his prolific research contributions and academic engagements. While specific awards are not explicitly listed, his academic and professional accolades can be inferred through his high-profile collaborations, participation in prestigious international congresses, and publication record in reputable journals such as Macromolecular Bioscience, Colloids and Surfaces B: Biointerfaces, and Applied Radiation and Isotopes. His role in European and multinational projects highlights the esteem in which his expertise is held by global researchers. Dr. Şenışık’s long-standing involvement in national medical physics congresses, as both a participant and presenter, underscores his recognition in Turkey’s scientific community. Moreover, his invitations to contribute to workshops organized by the International Atomic Energy Agency (IAEA) and other global bodies reflect his standing as a trusted academic voice in radiation safety and clinical physics. His administrative appointments at Altınbaş University, including commission memberships for accreditation and academic audits, further demonstrate institutional trust in his leadership. Collectively, these honors and roles mark him as a distinguished figure in his field. His broad recognition, coupled with consistent scholarly output and collaborative spirit, affirms his suitability for prestigious distinctions like the Best Researcher Award.

Conclusion

In conclusion, Dr. Ahmet Murat Şenışık exemplifies the ideal candidate for the Best Researcher Award. His career is marked by a unique blend of scientific inquiry, clinical expertise, and educational commitment. His multidisciplinary training in physics, nuclear sciences, and medical physics allows him to operate at the intersection of technology and patient care—pushing the boundaries of radiotherapy and nuclear medicine. His extensive publication record, conference participation, and involvement in innovative treatment technologies underscore his status as a forward-thinking researcher. Beyond his academic pursuits, Dr. Şenışık is a committed educator and administrator who actively shapes the next generation of healthcare professionals while contributing to institutional growth. His collaborative mindset and involvement in global research initiatives demonstrate not only his scientific capability but also his leadership in fostering international partnerships. Although continuous professional development remains an area to expand—especially in acquiring formal recognitions or fellowships from international bodies—his current achievements strongly position him as a leader in medical physics. With his dedication, multidisciplinary skills, and ongoing contributions to science and education, Dr. Şenışık stands out as a deserving recipient of the Best Researcher Award and a model academic in the evolving landscape of medical science

Asaad Ismail | Medical Physics | Best Researcher Award

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Prof Dr. Asaad Ismail | Medical Physics | Best Researcher Award

Physics chairman at Salahaddin University-erbil, Iraq

Ali Rezaei is an accomplished R&D and Product Manager specializing in nanotechnology and nanobiotechnology. With a strong research background, he has been involved in the development of high-performance nanocomposite materials. Ali has a reputation for his innovative approach and fast learning, contributing to successful projects in research and development. He was selected as the top researcher at Shahid Beheshti University in 2022 and is also a member of the National Elite Foundation of Iran. Ali’s strengths lie in his creativity, reliability, and persistence in solving complex problems and driving innovation.

Profile

Education 🎓

Bachelor of Biology (2015-2019) Gonbad Kavous University, Gonbad-e Qabus, Golestan, Iran GPA: 17.06 Ali completed his undergraduate studies in biology, with a focus on animal sciences. His academic performance during this period laid the groundwork for his future pursuits in nanobiotechnology. Master of Nanobiotechnology (2019-2022) Shahid Beheshti University, Tehran, Iran GPA: 19.36 Ali excelled in his master’s program, specializing in nanobiotechnology, which paved the way for his involvement in cutting-edge research and development in nanomaterials and practical applications of nanotechnology.

Experience 💼

R&D and Product Manager With one year of experience in the National Elite Foundation of Iran, Ali has worked as an R&D and Product Manager, contributing to the research and development of innovative nanocomposite materials. He has a deep understanding of product design, development, and registration processes. Ali gained significant experience as a research assistant in the nanobiotechnology laboratory of Shahid Beheshti University, where he honed his skills in nanotechnology and material science. His role involved researching high-performance nanomaterials and leading projects on practical applications of nanotechnology.

Awards and Honors 🏆

Top Researcher Award (2022) Ali was recognized as the top researcher at Shahid Beheshti University in 2022 for his outstanding contributions to nanotechnology research. National Elite Foundation Membership Ali was selected as a member of the National Elite Foundation of Iran, a prestigious acknowledgment of his exceptional skills, research achievements, and contributions to innovation in the field of nanotechnology.

Research Focus 🔬

Ali’s research focuses on nanobiotechnology, particularly in the development and application of nanocomposite materials. His work aims at designing and producing high-performance nanomaterials for practical applications. He is passionate about innovative nanotechnology, constantly seeking new resources, techniques, and solutions to push the boundaries of product development and registration in the nanotechnology sector.

Conclusion

Ali Rezaei is a highly suitable candidate for the Best Researcher Award, thanks to his strong academic background, significant research experience, and recognition as a top researcher. His skills and attributes position him well for future contributions to the field of nanotechnology. By addressing areas for improvement, such as expanding his research portfolio and increasing his publication output, Ali can further enhance his qualifications and continue to make impactful advancements in his field.

Publication Top Notes

 

  • Indoor Radon Concentration and Its Health Risks in Selected Locations in Iraqi Kurdistan Using CR-39 NTDs
    • Authors: AH Ismail, MS Jaafar
    • Source: 4th International Conference on Bioinformatics and Biomedical Engineering, 2010
    • Summary: This study examines indoor radon levels across various locations in Iraqi Kurdistan, assessing their potential health risks. Utilizing CR-39 nuclear track detectors (NTDs), the research highlights the implications of elevated radon exposure in residential settings.
  • Interaction of Low-Intensity Nuclear Radiation Dose with Human Blood: Using the New Technique of CR-39 NTDs for an In Vitro Study
    • Authors: AH Ismail, MS Jaafar
    • Source: Applied Radiation and Isotopes, 69(3), 559-566, 2011
    • Summary: The paper investigates how low-intensity nuclear radiation doses affect human blood using CR-39 NTDs. It emphasizes the innovative application of these detectors in assessing biological responses to radiation.
  • Design and Construct Optimum Dosimeter to Detect Airborne Radon and Thoron Gas: Experimental Study
    • Authors: AH Ismail, MS Jaafar
    • Source: Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2011
    • Summary: This research focuses on creating an efficient dosimeter for measuring airborne radon and thoron levels. The experimental approach involves optimizing the dosimeter’s design to enhance detection accuracy.
  • Measurement of Radium Content and Radon Exhalation Rates in Building Material Samples Using Passive and Active Detecting Techniques
    • Authors: AH Zakaria, SJ Mohamed, AH Ismail
    • Source: International Journal of Scientific & Engineering Research, 4(9), 1827-1831, 2013
    • Summary: This publication details the evaluation of radium content and radon exhalation rates in various building materials. It contrasts passive and active detection techniques, providing insights into material safety regarding radon emissions.
  • Experimental Measurements on CR-39 Response for Radon Gas and Estimating the Optimum Dimensions of Dosimeters for Detection of Radon
    • Authors: AH Ismail, MS Jaafar
    • Source: Proceedings of the 3rd Asian Physics Symposium, Bandung, Indonesia, 2009
    • Summary: This work discusses the response characteristics of CR-39 detectors to radon gas, aiming to determine optimal dosimeter dimensions for effective radon detection.
  • Study of Change in the Efficiency of CR-39 After Storage for Different Product Companies by Using TRACK_TEST Program
    • Author: AH Ismail
    • Source: Nuclear Instruments and Methods in Physics Research Section B: Beam Interactions with Materials and Atoms, 2009
    • Summary: The study evaluates the efficiency changes in CR-39 detectors after varying storage conditions, employing the TRACK_TEST program for analysis.
  • Radon Exhalation Rate from Building Materials Using Passive Technique Nuclear Track Detectors
    • Authors: ZA Hussein, MS Jaafar, AH Ismail, AA Battawy
    • Source: International Journal of Scientific & Engineering Research, 4(7), 1276-1282, 2013
    • Summary: This publication assesses the radon exhalation rates from building materials using passive nuclear track detectors, contributing valuable data for understanding building material safety.
  • Relationship Between Radon Concentration, Ventilation Rate, and Male Infertility: A Case Study in Iraqi Kurdistan
    • Authors: AH Ismail, MS Jaafar
    • Source: International Journal of Low Radiation, 7(3), 175-187, 2010
    • Summary: The study investigates the correlation between indoor radon concentrations, ventilation rates, and male infertility cases in Iraqi Kurdistan, indicating potential health implications of poor indoor air quality.
  • Analysis of Radon Concentrations in Drinking Water in Erbil Governorate (Iraqi Kurdistan) and Its Health Effects
    • Authors: AH Ismail, SO Haji
    • Source: Tikrit Journal of Pure Science, 13(3), 9, 2008
    • Summary: This research analyzes radon levels in drinking water within the Erbil Governorate, discussing the potential health effects associated with exposure through water consumption.
  • Comparison of Alexandrite and Diode Lasers for Hair Removal in Dark and Medium Skin: Which is Better?
    • Authors: FH Mustafa, MS Jaafar, AH Ismail, KN Mutter
    • Source: Journal of Lasers in Medical Sciences, 5(4), 188, 2014
    • Summary: This paper compares the efficacy of different laser types for hair removal on varying skin tones, contributing to dermatological practices.
  • Measurement of Radon Activity Concentration in Iraqi Kurdistan Soil by Using CR-39 Nuclear Track Detectors
    • Author: AH Ismail
    • Source: Salahaddin University-Erbil, 2004
    • Summary: This publication focuses on measuring radon activity concentrations in the soil of Iraqi Kurdistan, emphasizing environmental health risks.
  • Hazards Assessment of Radon Exhalation Rate and Radium Content in the Soil Samples in Iraqi Kurdistan Using Passive and Active Detecting Methods
    • Authors: AH Ismail, MS Jaafar
    • Source: International Journal of Environmental and Ecological Engineering, 4(10), 2010
    • Summary: The study assesses radon exhalation rates and radium content in soil samples, utilizing both passive and active detection methods to evaluate potential environmental hazards.
  • Indoor Radon Concentration Measurement in Selected Factories in Northern and Central Iraq
    • Authors: AA Battawy, MS Jaafar, NF Tawfiq, IS Mustafa, AH Ali, ZA Hussein
    • Source: Measurement, 4(5), 2013
    • Summary: This publication measures indoor radon concentrations in various factories, highlighting occupational health risks associated with radon exposure.
  • Modelling of Indoor Radon Activity Concentration Dynamics and Its Validation Through In-Situ Measurements on Regional Scale
    • Authors: S Mancini, M Guida, A Cuomo, D Guida, AH Ismail
    • Source: AIP Conference Proceedings, 1982(1), 2018
    • Summary: The study models indoor radon activity concentration dynamics, validating the model with in-situ measurements to assess regional radon exposure risks.
  • Measurements of Indoor Radon-222 Concentration Inside Iraqi Kurdistan: Case Study in the Summer Season
    • Authors: ZA Hussein, MS Jaafar, AH Ismail
    • Source: Journal of Nuclear Medicine and Radiation Therapy, 4(143), 2013
    • Summary: This case study examines indoor radon-222 concentrations in Iraqi Kurdistan during the summer, providing critical data on seasonal variations in radon levels.
  • Influences of Different Low-Level Laser Power at Wavelength 635 nm for Two Types of Skin: Dark and Light
    • Authors: F Hamad, M Jaafar, A Hamid, A Omar, Z Timimi, H Houssein
    • Source: Proceedings of the 7th IMT-GT UNINET and the 3rd International PSU-UNS Conference, 2009
    • Summary: This research evaluates the effects of laser power variations on different skin types, contributing to the field of dermatological laser treatments.
  • Radiation Exposure of Leukemia Blood Samples and Its Impacts on the Density of RBC, WBC, and PLT: In Vitro
    • Authors: AH Ismail, MA Hamad, EMT Harki
    • Source: Scientific Research Publishing, 2012
    • Summary: The study assesses the impact of radiation exposure on leukemia blood samples, focusing on the changes in blood cell densities.
  • The Effect of Laser Wavelength in Photodynamic Therapy and Phototherapy for Superficial Skin Diseases
    • Authors: FH Mustafa, MS Jaafar, AH Ismail, HAA Houssein
    • Source: 2011 IEEE International Conference on Imaging Systems and Techniques, 232-236, 2011
    • Summary: This research explores how different laser wavelengths affect photodynamic therapy and phototherapy outcomes for superficial skin diseases.
  • Influence of the Static Magnetic Field on Red Blood Cells Parameters and Platelets Using Tests of CBC and Microscopy Images
    • Authors: BT Mustafa, SP Yaba, AH Ismail
    • Source: Biomedical Physics & Engineering Express, 6(2), 025004, 2020
    • Summary: The study investigates the effects of static magnetic fields on red blood cells and platelets, utilizing comprehensive blood tests and microscopy for analysis.

Bibiana Doris Riquelme | Biomedical Physics | Best Researcher Award

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Bibiana Doris Riquelme | Biomedical Physics | Best Researcher Award

Principal Research, Consejo Investigaciones Universidad Nacional de Rosario (CIUNR), Argentina.

Bibiana Doris Riquelme is a distinguished physicist based in Rosario, Argentina, with extensive expertise in applied physics, biophotonics, hemorrheology, and biosensors. Her interdisciplinary approach combines principles of physical sciences and biomedical research, leading to significant advancements in understanding biomolecular interactions and their applications in medical technology. Riquelme is affiliated with the Institute of Physics of Rosario (IFIR), where she continues to contribute to innovative research initiatives.

Profile:

 

Education

Riquelme completed her Bachelor’s Degree in Physics from the National University of Rosario (UNR) in December 1989, specializing in applied optics to biology. She further advanced her education by earning a Doctorate in Physics in May 1997, focusing on the complex rheology of biomembranes and its application to human erythrocytes. Additionally, she holds a degree as a Professor of Drawing and Painting from S.S.M. Cosmopolita, demonstrating her diverse academic background and creative skills.

Professional Experiences

Bibiana Riquelme’s professional journey includes a postdoctoral fellowship awarded by FOMEC at the National University of Rosario, where she spent ten months abroad in France, engaged in research at the Laboratory of Mechanics and Cellular and Tissue Engineering. Her work in various esteemed institutions has allowed her to collaborate with leading researchers and contribute to significant advancements in her field. Currently, she is a research scientist at the Institute of Physics of Rosario, where she leads projects focusing on optics and biophysics.

 

Research skills

Riquelme possesses a comprehensive skill set in several critical areas of research, including optics, biophotonics, and hemorrheology. Her proficiency extends to the design and development of biosensors and the study of biomolecular interactions in solution. Her expertise in applied optics to biomedical sciences enables her to contribute significantly to both theoretical and practical advancements in health-related technologies, including medical biomaterials and stem cell technologies.

 

Awards And Recoginition

Throughout her career, Riquelme has received recognition for her contributions to science and technology. Her postdoctoral research experience and collaborations with international research institutions highlight her commitment to advancing knowledge in her field. While specific awards and recognitions are not detailed in the provided information, her standing as a researcher in the academic community reflects her impactful work and dedication to scientific excellence.

Conclusion

Bibiana Doris Riquelme possesses a robust academic background, specialized research expertise, and postdoctoral experience, making her a strong candidate for the Best Researcher Award. Her contributions to applied physics in the biomedical field and her potential for impactful research underscore her suitability for this recognition. Addressing the areas for improvement, particularly in showcasing her publications and community engagement, could further bolster her candidacy and demonstrate her influence within the scientific community.

Publication Top Notes

  • Preliminary Study of the Gamma-Radiation Effect on the Plasma Ions Concentration in Transfusion Units
    Authors: Alet, A.I., Porini, S., Detarsio, G., Galassi, M.E., Riquelme, B.D.
    Year: 2024
    Citation: Anales de la Asociacion Fisica Argentina, 35(1), pp. 21–24.
    🧪📊
  • Effect of Aqueous Extracts of Phyllanthus sellowianus on the Viscoelastic Properties of Human Red Blood Cells: In Vitro Antidiabetic Activity
    Authors: Mascaro Grosso, H., Buszniez, P., Castellini, H.V., Riquelme, B.D.
    Year: 2023
    Citation: Anales de la Asociacion Fisica Argentina, 34(2), pp. 42–45.
    🍃💉
  • Biospeckle Laser as a Tool to Analyze Erythrocyte Aggregation
    Authors: Toderi, M.A., Riquelme, B.D., Galizzi, G.E.
    Year: 2022
    Citation: Optical Engineering, 61(12), 124101.
    🔬✨
  • Methods: A New Protocol for In Vitro Red Blood Cell Glycation
    Authors: Batista da Silva, M.V., Alet, A.I., Castellini, H.V., Riquelme, B.D.
    Year: 2022
    Citation: Comparative Biochemistry and Physiology – Part A: Molecular and Integrative Physiology, 264, 111109.
    📚🧬
  • New Insights into the Mechanics of Erythrocytes: Effects of Radiation and Several Drugs of Biomedical Interest
    Authors: Riquelme, B.D., Toderi, M., Batista, M., Estrada, E., Alet, A.I.
    Year: 2022
    Citation: Series on Biomechanics, 36(1), pp. 61–69.
    🩸🔍
  • In Vitro Alteration on Erythrocytes Mechanical Properties by Propofol, Remifentanil, and Vecuronium
    Authors: Alet, A.I., Batista da Silva, M.V., Castellini, H.V., Alet, N.A., Riquelme, B.D.
    Year: 2021
    Citation: Microvascular Research, 135, 104132.
    💊🩹
  • New Insights into the Analysis of Red Blood Cells from Leukemia and Anemia Patients: Nonlinear Quantifiers, Fractal Mathematics, and Wavelet Transform
    Authors: Bortolato, S.A., Mancilla Canales, M.A., Riquelme, B.D., Ponce de León, P., Korol, A.M.
    Year: 2021
    Citation: Physica A: Statistical Mechanics and its Applications, 567, 125645.
    📈💔
  • Simultaneous Determination of Human Erythrocyte Deformability and Adhesion Energy: A Novel Approach Using a Microfluidic Chamber and the “Glass Effect”
    Authors: Londero, C.M., Riquelme, B.D.
    Year: 2021
    Citation: Cell Biochemistry and Biophysics, 79(1), pp. 49–55.
    🔬💧
  • Preliminary Study of the Effects of Gamma Radiations on Human Red Blood Cells
    Authors: Estrada, E., Castellini, H., Acosta, A., Riquelme, B.D., Galassi, M.E.
    Year: 2020
    Citation: Anales de la Asociacion Fisica Argentina, 31(2), pp. 51–54.
    ☢️🔴
  • Extensive Clinical, Serologic and Molecular Studies Lead to the First Reported Rhmod Phenotype in Argentina
    Authors: Mufarrege, N., Franco, N., Trucco Boggione, C., Castilho, L., Cotorruelo, C.
    Year: 2020
    Citation: Transfusion, 60(7), pp. 1373–1377.
    🩸🇦🇷

Manijeh Beigi | Medical Physics | Best Researcher Award

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Assist Prof Dr. Manijeh Beigi | Medical Physics | Best Researcher Award

Assistant Professor in Medical Physics, Iran University of Medical Sciences, Iran.

Dr. Manijeh Beigi, Ph.D., an Assistant Professor at Iran University of Medical Sciences, excels in radiotherapy physics with a focus on radiotherapy toxicity, radiomics, dosiomics, and advanced MR imaging. She completed her Ph.D. at Tehran University of Medical Sciences, researching diffusion tensor imaging for radiotherapy treatment planning. Her career includes significant roles at Imam Hosein Hospital, Haft-e-Tir Hospital, and Pardis Niloo Cancer Center, where she has specialized in 3D conformal and IMRT radiotherapy, dosimetry, and quality assurance. Dr. Beigi’s research has led to numerous high-impact publications and conference presentations. As a dedicated educator, she supervises several student theses and manages research projects. Recognized for her exceptional academic achievements, including top rankings in national entrance exams, Dr. Beigi is a leading figure in her field, combining innovative research with strong leadership and mentorship skills.

Profile:

Education

Dr. Manijeh Beigi earned her Ph.D. in Medical Physics from Tehran University of Medical Sciences in 2018. Her doctoral research focused on applying diffusion tensor imaging (DTI) for radiotherapy treatment planning, specifically aiming to determine the glioma’s clinical target volume for intensity-modulated radiotherapy (IMRT) using a combination of quantitative information from multiparametric MR imaging. Prior to this, Dr. Beigi completed her Master of Science in Medical Physics at Tarbiat Modares University in 2010, where her thesis examined the quality audit of radiotherapy dosimetry under various conditions. Her educational background reflects a strong foundation in both theoretical and applied aspects of medical physics, with a particular emphasis on radiotherapy and imaging technologies. This advanced training has equipped her with the expertise to contribute significantly to research and clinical practice in radiation oncology.

Professional Experience

Dr. Manijeh Beigi, Ph.D., is an esteemed professional in the field of medical physics with extensive experience in radiotherapy and dosimetry. Currently serving as an Assistant Professor at Iran University of Medical Sciences, she specializes in radiotherapy physics, teaching radiation oncology residents, and managing research projects. Her previous roles include Radiotherapy Physicist positions at Imam Hosein Hospital, Haft-e-Tir Hospital, and Pardis Niloo Cancer Center, where she conducted 3D Conformal and IMRT treatment planning, dosimetry, and quality assurance for various linear accelerators. Dr. Beigi also has a background as a Research Assistant in the Quantitative MR Imaging and Spectroscopy Group at Tehran University of Medical Sciences, focusing on MR imaging and spectroscopy for treatment planning. Her professional journey showcases her comprehensive expertise in radiotherapy, from clinical practice to advanced research in radiomics and dosiomics.

Research Interest

Dr. Manijeh Beigi’s research focuses on the intersection of advanced imaging and treatment planning in radiotherapy. Her primary interests include investigating radiotherapy toxicity and enhancing treatment plan quality through radiomics and dosiomics. She is dedicated to quantitatively assessing tumor responses to treatment and applying advanced magnetic resonance (MR) imaging techniques in radiotherapy (RT) planning. Dr. Beigi’s work explores the integration of diffusion tensor imaging (DTI) with traditional MR imaging methods to improve the accuracy of glioma treatment planning. Her research also emphasizes the development of innovative dosimetric approaches to predict and mitigate toxicity in patients undergoing radiotherapy. Through her exploration of these advanced methodologies, Dr. Beigi aims to refine treatment protocols, optimize patient outcomes, and contribute to the ongoing advancement of precision medicine in oncology. Her efforts reflect a commitment to both the theoretical and practical aspects of medical physics.

Research Skills

Dr. Manijeh Beigi demonstrates exceptional research skills in the field of medical physics, particularly within radiotherapy. Her expertise includes advanced radiotherapy techniques, such as 3D conformal and IMRT treatment planning, and extensive dosimetric quality assurance. Dr. Beigi excels in the application of radiomics and dosiomics, employing quantitative assessments and advanced MR imaging to enhance treatment planning and predict patient toxicity. Her Ph.D. research on using diffusion tensor imaging (DTI) for glioma treatment planning showcases her ability to integrate complex imaging modalities with clinical applications. Dr. Beigi’s proficiency extends to managing and supervising research projects, writing successful grant proposals, and leading interdisciplinary teams. Her publication record, featuring high-impact journal articles and conference contributions, reflects her commitment to advancing the field. Overall, Dr. Beigi’s research skills are marked by innovation, technical proficiency, and a strong focus on improving patient outcomes in radiotherapy.

Award and Recognitions

Dr. Manijeh Beigi has achieved significant recognition in her field, reflecting her outstanding contributions to medical physics and radiotherapy. She has been consistently ranked in the top 1% in national entrance exams for both her Ph.D. and postgraduate studies, underscoring her academic excellence. Dr. Beigi’s research on radiotherapy toxicity, radiomics, and advanced MR imaging has garnered attention in prestigious journals and conferences. Her innovative work, particularly in applying diffusion tensor imaging (DTI) for treatment planning, has been highlighted in high-impact publications like Cancer Imaging Journal and Journal of Neurooncology. Her contributions were also showcased at notable conferences, including the AAPM and ESTRO. These accolades demonstrate Dr. Beigi’s commitment to advancing her field and her recognition as a leading expert in radiotherapy and medical physics.

Conclusion

Dr. Manijeh Beigi is a highly qualified candidate for the Research for Best Researcher Award. Her extensive research contributions, innovative approaches in radiotherapy, and leadership in academic and clinical settings highlight her suitability for this recognition. Addressing areas for improvement, such as expanding collaborations and increasing public engagement, could further enhance her already significant impact on the field of medical physics. Her dedication to advancing radiotherapy and her proven track record of excellence make her a strong contender for the award.

Publication Top Notes

  1. Title: Safe bunker designing for the 18 MV Varian 2100 Clinac: A comparison between Monte Carlo simulation based upon data and new protocol recommendations
    Authors: HG Manije Beigi, Fatemeh Afarande
    Journal: Reports of Practical Oncology and Radiotherapy
    Year: 2016
    Volume: 21
    Pages: 42-49
    Citations: 12
  2. Title: Heterogeneity analysis of diffusion-weighted MRI for prediction and assessment of microstructural changes early after one cycle of induction chemotherapy in nasopharyngeal carcinoma
    Authors: M Beigi, AF Kazerooni, M Safari, M Alamolhoda, MS Moghdam, …
    Journal: La Radiologia Medica
    Year: 2018
    Volume: 123
    Pages: 36-43
    Citations: 9
  3. Title: Findings of DTI-p maps in comparison with T2/T2-FLAIR to assess postoperative hyper-signal abnormal regions in patients with glioblastoma
    Authors: M Beigi, M Safari, A Ameri, MS Moghadam, A Arbabi, M Tabatabaeefar, …
    Journal: Cancer Imaging
    Year: 2018
    Volume: 18
    Article: 1-7
    Citations: 5
  4. Title: Intracellular delivery of anticancer agents using dual responsive nanomicelles synthesized via RAFT polymerization
    Authors: M Esmaeili, S Shahbaz, M Kamankesh, M Shahin, FSM Tekie, P Fadavi, …
    Journal: European Polymer Journal
    Year: 2023
    Volume: 198
    Article: 112417
    Citations: 2
  5. Title: Shuffle-ResNet: Deep learning for predicting LGG IDH1 mutation from multicenter anatomical MRI sequences
    Authors: LA Mojtaba Safari, Manjieh Beiki, Ahmad Ameri, Saeed Hosseini Toudeshki, …
    Journal: Biomedical Physics & Engineering Express
    Year: 2022
    Volume: 8 (6)
    Citations: 2
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