PEER-REVIEWED PUBLICATION

2020

Effect of Cyclic Stretch on Neuron Reorientation and Axon Outgrowth

A tensile test divider icon

Lin J, Li X, et al.

Frontiers in Bioengineering and Biotechnology

Zhejiang University

RESEARCH SUMMARY
This study investigated how cyclic uniaxial stretch influences neuronal alignment and neurite extension using PC12 cells cultured on elastomeric PDMS substrates. Using controlled stretch programs spanning amplitudes of 2–10% and frequencies of 0.05–0.25 Hz over up to 120 h, the authors quantified neurite orientation distributions and axon length from fluorescence images. Neurons exhibited clear, thresholded reorientation behavior: when stretch amplitude and frequency were sufficiently high (notably ≥5% at 0.25 Hz), cells progressively polarized toward orientations perpendicular to the stretch direction, with the fraction of perpendicularly aligned cells increasing over time. In contrast, axon elongation (mean axon length) increased with culture time but remained largely insensitive to cyclic stretch across tested conditions. To explain these results, a mechanochemical model coupling focal adhesion bond kinetics, stress fiber viscoelastic/contractile force generation, and microtubule/tubulin-driven axon growth was developed; the framework reproduced the frequency/amplitude dependence of reorientation and predicted negligible effects on axon growth for zero-mean cyclic stretch because average traction levels remain similar to static conditions.
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CELLSCALE INSTRUMENT USED

MechanoCulture T6

A CellScale MechanoCulture T6 was used as a controllable stretching platform to apply cyclic uniaxial deformation to PDMS films seeded with PC12 cells. PDMS strips (20×60 mm,~1 mm thick) were sterilized, poly-L-lysine treated, and clamped in the bioreactor chamber containing culture medium. After ~4 h cell attachment, substrates were subjected to programmed cyclic stretch with amplitudes of 2–10% and frequencies of 0.05–0.25 Hz for up to 120 h (with slight pre-stretch to prevent wrinkling). This CellScale-enabled mechanical stimulation provided the core experimental variable used to quantify time-dependent neuron reorientation (angle distributions relative to stretch axis) and to compare axon length evolution under different stretch regimes versus no-stretch controls.
AUTHORS

Ji Lin, Xiaokeng Li, Jun Yin, Jin Qian.

PUBLICATION DETAILS
JOURNAL

Frontiers in Bioengineering and Biotechnology

YEAR

2020

INSTITUTIONS

Zhejiang University

COUNTRIES

China

INSTRUMENT USED

MechanoCulture T6

TESTING METHODS

Hydrated and Temperature Controlled TestingTensile Testing

RESEARCH APPLICATIONS

MechanotransductionNeural Tissue & CNS MechanicsPeripheral Nerve Regeneration & PNS Mechanics

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