Masumeh Kazemi
Bio
As a Visiting Assistant Professor at Wentworth Institute of Technology (WIT), I have taught a range of courses in mechanical engineering, biomechanics, additive manufacturing, materials science, and numerical methods. My research bridges materials science, additive manufacturing, and biomedical engineering, with a strong focus on both experimental and computational approaches.
I completed my postdoctoral research at Boston University, where I led the development of a state-of-the-art Raman spectroscopy platform for the non-invasive prediction of tissue mechanical properties. This NIH-funded work aimed to detect early-stage cartilage pathology and was benchmarked against compositional MRI (T2 mapping). I also contributed to other NIH- and foundation-supported studies, including projects funded by the Musculoskeletal Transplant Foundation (MTF) and the Arthritis Foundation.
During my Ph.D. studies at the University of Memphis, I investigated the biomechanics of cartilage and bone by integrating experimental techniques with multiscale finite element modeling to study stress–strain distributions and mechanobiological signal transduction. My academic background is grounded in materials science and engineering, with a B.S. and M.S. focused on enhancing the mechanical properties of structural materials.
My interdisciplinary research has included gait analysis of post-operative knee patients, mechanical evaluation of FDM 3D-printed components, and tissue health assessment using spectroscopy and imaging technologies. These projects reflect my commitment to applying engineering fundamentals to real-world challenges in health, safety, and human performance.
Beyond my technical expertise, I have secured competitive research funding, mentored diverse student teams, and published in leading journals across biomechanics, mechanical engineering, and additive manufacturing. I have also presented my work at national and international conferences and remain deeply committed to collaborative, impactful research and education.
Accomplishments
I have led multidisciplinary research in additive manufacturing, biomechanics, and materials science, resulting in high-impact publications, funded proposals, and a patent on enhancing cast iron properties with steel reinforcement. I apply mechanics fundamentals to study stress–strain distribution in soft and hard tissues (cartilage and bone), and I use Raman-based spectroscopy to predict tissue mechanical properties for cartilage diagnostics. My work also focuses on predicting the quality of additively manufactured parts. I supervise graduate research bridging mechanical and biomedical engineering and emphasize hands-on, industry-relevant teaching at all levels.
Research Interests
My research interests lie at the intersection of additive manufacturing, biomechanics, advanced materials, and intelligent systems, unified by a focus on process-structure-property-performance relationships and real-time optimization. I develop experimental and computational frameworks to improve the mechanical performance, reliability, and sustainability of structural and biomedical systems.
In metal additive manufacturing, I investigate process-structure-performance linkages using in-situ monitoring, sensor data integration, and machine learning to develop intelligent closed-loop control systems. This work supports the fabrication of defect-free, high-performance components for aerospace, defense, and biomedical applications.
In parallel, my research in biomechanics applies solid mechanics principles to understand the behavior of soft and hard tissues. I develop multiscale finite element models and use techniques like Raman spectroscopy to non-invasively assess tissue properties and detect early-stage degeneration. I am also exploring the design of smart implants that leverage engineered materials and integrated sensing for personalized medicine.
Overall, my work bridges advanced manufacturing and biomedical engineering through experimental characterization, data-driven modeling, and system-level design. I am committed to interdisciplinary collaboration and the translation of research into practical solutions that advance both industry and human health.