MyoRobot 2.0: An advanced biomechatronics platform for automated, environmentally controlled skeletal muscle single fiber biomechanics assessment employing inbuilt real-time optical imaging

Haug M, Meyer C, Reischl B, Prölß G, Nübler S, Schürmann S, Schneidereit D, Heckel M, Pöschel T, Rupitsch S, Friedrich O (2019)

Publication Type: Journal article

Publication year: 2019

Journal

Biosensors and Bioelectronics Elsevier

Book Volume: 138

Article Number: 111284

DOI: 10.1016/j.bios.2019.04.052

Abstract

We present an enhanced version of our previously engineered MyoRobot system for reliable, versatile and automated investigations of skeletal muscle or linear polymer material (bio)mechanics. That previous version already replaced strenuous manual protocols to characterize muscle biomechanics properties and offered automated data analysis. Here, the system was further improved for precise control over experimental temperature and muscle single fiber sarcomere length. Moreover, it also now features the calculation of fiber cross-sectional area via on-the-fly optical diameter measurements using custom-engineered microscope optics. With this optical systems integration, the MyoRobot 2.0 allows to tailor a wealth of recordings for relevant physiological parameters to be sequentially executed in living single myofibers. Research questions include assessing temperature-dependent performance of active or passive biomechanics, or automated control over length-tension or length-velocity relations. The automatically obtained passive stress-strain relationships and elasticity modules are important parameters in (bio)material science. From the plethora of possible applications, we validated the improved MyoRobot 2.0 by assessing temperature-dependent myofibrillar Ca ²⁺ sensitivity, passive axial compliance and Young's modulus. We report a Ca ²⁺ desensitization and a narrowed dynamic range at higher temperatures in murine M. extensor digitorum longus single fibers. In addition, an increased axial mechanical compliance in single muscle fibers with Young's moduli between 40 - 60 kPa was found, compatible with reported physiological ranges. These applications demonstrate the robustness of our MyoRobot 2.0 for facilitated single muscle fiber biomechanics assessment.

Authors with CRIS profile

Michael Haug Lehrstuhl für Medizinische Biotechnologie Charlotte Meyer Lehrstuhl für Medizinische Biotechnologie Barbara Reischl Lehrstuhl für Medizinische Biotechnologie Gerhard Prölß Lehrstuhl für Medizinische Biotechnologie Stefanie Nübler Lehrstuhl für Medizinische Biotechnologie Sebastian Schürmann Lehrstuhl für Medizinische Biotechnologie Dominik Schneidereit Lehrstuhl für Medizinische Biotechnologie Michael Heckel Lehrstuhl für Multiscale Simulation of Particulate Systems Thorsten Pöschel Lehrstuhl für Multiscale Simulation of Particulate Systems Stefan Rupitsch Lehrstuhl für Autonome Systeme und Mechatronik Oliver Friedrich Lehrstuhl für Medizinische Biotechnologie

Related research project(s)

Advanced Biomechatronics Technology: Development and Application Jan. 1, 2017 - Dec. 31, 2018 Engineering of an automated biomechanics robot (MyoRobot) for advanced biomechanical functional testing in elastic and contractile tissues for biomedical research and preclinical diagnostics May 1, 2015 - April 30, 2018

How to cite

APA:

Haug, M., Meyer, C., Reischl, B., Prölß, G., Nübler, S., Schürmann, S.,... Friedrich, O. (2019). MyoRobot 2.0: An advanced biomechatronics platform for automated, environmentally controlled skeletal muscle single fiber biomechanics assessment employing inbuilt real-time optical imaging. Biosensors and Bioelectronics, 138. https://dx.doi.org/10.1016/j.bios.2019.04.052

MLA:

Haug, Michael, et al. "MyoRobot 2.0: An advanced biomechatronics platform for automated, environmentally controlled skeletal muscle single fiber biomechanics assessment employing inbuilt real-time optical imaging." Biosensors and Bioelectronics 138 (2019).

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