M
Mohamad Parnianpour
Researcher at Sharif University of Technology
Publications - 283
Citations - 8606
Mohamad Parnianpour is an academic researcher from Sharif University of Technology. The author has contributed to research in topics: Trunk & Isometric exercise. The author has an hindex of 50, co-authored 274 publications receiving 7835 citations. Previous affiliations of Mohamad Parnianpour include New York University & Hong Kong Polytechnic University.
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Journal Article
Modeling of functional trunk muscle performance : Interfacing ergonomics and spine rehabilitation in response to the ADA
TL;DR: The strength regressions developed in this study would provide dynamic strength limits that can be used as functional constraints in the computer simulation of physical activities, such as lifting.
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A method for developing biomechanical profiles of hand-intensive tasks.
TL;DR: Multi-variable biomechanical profiling can provide insight into effects of work design on workers; however, to achieve statistical significance large numbers of subjects are needed.
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Simulation of manual materials handling: biomechanival assessment under different lifting conditions
TL;DR: A two-dimensional sagittally symmetric human-body model was established to compute the moment and joint load time histories for MMH tasks for a variety of different lift specifications and constraints such as lifting durations, loads, and modes.
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Determination of the effect of lift characteristics on dynamic performance profiles during manual materials handling tasks
TL;DR: A methodology for using inferential statistics to evaluate the effect of lift characteristics on phase-dependent and phase-independent variability in performance and allows identification of the lift characteristics that dominate the variability of task demands, hence aiding in the design and assessment of ergonomic solutions.
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A novel approach to evaluate abdominal coactivities for optimal spinal stability and compression force in lifting.
TL;DR: Results indicate that higher abdominal coactivities should be avoided during heavier lifting tasks as they reduce stability margin while increasing spinal loads.