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   https://doi.org/10.1021/acsbiomaterials.3c01078  

   Johnson, Nicholas; Filler, Andrea C.; Sethi, Akash; Smith, Lucas R.; Leach, J. Kent (December 2023, ACS Biomaterials Science & Engineering)
2. Muscle on demand

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   Hess, Henry (August 2021, Nature Materials)

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3. Simplified Cost Functions Meet Advanced Muscle Models to Streamline Muscle Force Estimation

   https://doi.org/10.3390/biomed4030028  

   Ahmed, Muhammad Hassaan; N’Guessan, Jacques-Ezechiel; Das, Ranjan; Leineweber, Matthew; Goyal, Sachin (September 2024, BioMed)

   Background/Objectives: This study explores an optimization-based strategy for muscle force estimation by employing simplified cost functions integrated with physiologically relevant muscle models. Methods: Considering elbow flexion as a case study, we employ an inverse-dynamics approach to estimate muscle forces for the biceps brachii, brachialis, and brachioradialis, utilizing different combinations of cost functions and muscle constitutive models. Muscle force generation is modeled by accounting for active and passive contractile behavior to varying degrees using Hill-type models. In total, three separate cost functions (minimization of total muscle force, mechanical work, and muscle stress) are evaluated with each muscle force model to represent potential neuromuscular control strategies without relying on electromyography (EMG) data, thereby characterizing the interplay between muscle models and cost functions. Results: Among the evaluated models, the Hill-type muscle model that incorporates both active and passive properties, combined with the stress minimization cost function, provided the most accurate predictions of muscle activation and force production for all three arm flexor muscles. Our results, validated against existing biomechanical data, demonstrate that even simplified cost functions, when paired with detailed muscle models, can achieve high accuracy in predicting muscle forces. Conclusions: This approach offers a versatile, EMG-free alternative for estimating muscle recruitment and force production, providing a more accessible and adaptable tool for muscle force analysis. It has profound implications for enhancing rehabilitation protocols and athletic training, not only broadening the applicability of muscle force estimation in clinical and sports settings but also paving the way for future innovations in biomechanical research. 

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4. 3D printing a biocompatible elastomer for modeling muscle regeneration after volumetric muscle loss

   https://doi.org/10.1016/j.bioadv.2022.213171  

   Kiratitanaporn, Wisarut; Berry, David B.; Mudla, Anusorn; Fried, Trevor; Lao, Alison; Yu, Claire; Hao, Nan; Ward, Samuel R.; Chen, Shaochen (November 2022, Biomaterials Advances)
5. Reduced non-bicarbonate skeletal muscle buffering capacity in mice with the mini-muscle phenotype

   https://doi.org/10.1242/jeb.172478  

   Kay, Jarren C.; Ramirez, Jocelyn; Contreras, Erick; Garland, Theodore (May 2018, The Journal of Experimental Biology)