Applying Physiologically Relevant Strains to Tenocytes in an In Vitro Cell Device Induces In Vivo Like Behaviors

We have developed a novel cell stretching device (called Cell Gym) capable of applying physiologically relevant low magnitude strains to tenocytes on a collagen type I coated membrane. We validated our device thoroughly on two levels: (1) substrate strains, (2) cell level strains. Our cell level str...

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Bibliographic Details
Published inJournal of biomechanical engineering Vol. 138; no. 12
Main Authors Joo Kim, Jung, Musson, David S, Matthews, Brya G, Cornish, Jillian, Anderson, Iain A, Shim, Vickie B
Format Journal Article
LanguageEnglish
Published United States 01.12.2016
Subjects
Animals
Biomimetics - instrumentation
Cell Size
Cells, Cultured
Collagen - biosynthesis
Compressive Strength - physiology
Elastic Modulus - physiology
Equipment Design
Equipment Failure Analysis
Female
Mechanotransduction, Cellular - physiology
Micro-Electrical-Mechanical Systems - instrumentation
Micromanipulation - instrumentation
Physical Stimulation - instrumentation
Rats
Rats, Wistar
Stress, Mechanical
Tenocytes - cytology
Tenocytes - physiology
Tensile Strength - physiology
Tissue Scaffolds
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Summary:We have developed a novel cell stretching device (called Cell Gym) capable of applying physiologically relevant low magnitude strains to tenocytes on a collagen type I coated membrane. We validated our device thoroughly on two levels: (1) substrate strains, (2) cell level strains. Our cell level strain results showed that the applied stretches were transferred to cells accurately (∼90%). Our gene expression data showed that mechanically stimulated tenocytes (4%) expressed a lower level of COL I gene. COX2 gene was increased but did not reach statistical significance. Our device was then tested to see if it could reproduce results from an in vivo study that measured time-dependent changes in collagen synthesis. Our results showed that collagen synthesis peaked at 24 hrs after exercise and then decreased, which matched the results from the in vivo study. Our study demonstrated that it is important to incorporate physiologically relevant low strain magnitudes in in vitro cell mechanical studies and the need to validate the device thoroughly to operate the device at small strains. This device will be used in designing novel tendon tissue engineering scaffolds in the future.
ISSN:1528-8951
DOI:10.1115/1.4034031