Robert S. Cargill scite author profile

The mechanism by which mechanical impact to brain tissue is transduced to neuronal impairment remains poorly understood. Using an in vitro model of neuronal stretch, we found that mechanical stretch of neurons resulted in a transient plasma membrane permeability increase. Primary cortical neurons, seeded on silicone substrates, were subjected to a defined rate and magnitude strain pulse by stretching the substrates over a fixed cylindrical form. To identify plasma membrane defects, various sized fluorescent molecules were added to the bathing media either immediately before injury or 1, 2, 5, or 10 min after injury and removed one minute later. The percent of cells that took up dye depended on the applied strain rate, strain magnitude and molecular size. Severe stretch (10 sec(-1), 0.30) resulted in significant uptake of all tested molecules (ranging between 0.5 and 8.9 nm radii) with up to 60% of cells positively stained. Furthermore, the neurons remained permeable to the smallest molecule (carboxyfluorescein, 380 Da) up to 5 min after severe stretch but were only permeable to larger molecules (>/=10 kDa) immediately after stretch. These transiently formed membrane defects may be the initiating mechanism that translates mechanical stretch to cellular dysfunction.

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High rate shear strain of three-dimensional neural cell cultures: a new in vitro traumatic brain injury model

LaPlaca

Cullen

McLoughlin

et al. 2005

Journal of Biomechanics

194

153

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Acute Alterations in [Ca²⁺]_iin NG108-15 Cells Subjected to High Strain Rate Deformation and Chemical Hypoxia: Anin VitroModel for Neural Trauma

Cargill

Thibault²

1996

Journal of Neurotrauma

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The short-term (less than 2 min) alterations in the intracellular free calcium concentration in differentiated NG108-15 (neuroblastoma cross glioma) cells exposed to dynamic mechanical deformation with and without superimposed chemical hypoxia were determined. A previously developed device, modified for these studies, was used to apply deformations at a magnitude and rate representative of those experienced by neural tissue in Traumatic Brain Injury. Chemical hypoxia was imposed using a combination of 2-deoxy-D-glucose and salicylate, anaerobic and aerobic metabolic blockers, respectively. Real time measurement of intracellular free calcium concentration using Fura-2 and a custom epifluorescence microscopy system provided a quantitative index of cell response. At high rates of deformation (approximately 10 sec-1), increases in intracellular free calcium concentration were exponentially related to the magnitude of the applied deformation. Chemical hypoxia had no effect on this acute response. At low rates of deformation, small increases in intracellular free calcium concentration were independent of the magnitude of the deformation. These findings indicate that strategies for reducing severity of TBI should focus on minimizing the rate of deformation of neural cells. Together with data from animal, physical, and finite element models, these data can be employed in the development of physiologic injury tolerance criteria for the whole head.

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Susceptibility of hippocampal neurons to mechanically induced injury

Geddes

LaPlaca

Cargill

2003

Experimental Neurology

109

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An in Vitro Model of Neural Trauma: Device Characterization and Calcium Response to Mechanical Stretch

Geddes

Cargill

2001

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An in vitro model for neural trauma was characterized and validated. The model is based on a novel device that is capable of applying high strain rate, homogeneous, and equibiaxial deformation to neural cells in culture. The deformation waveform is fully arbitrary and controlled via closed-loop feedback. Intracellular calcium ([Ca2+]i) alterations were recorded in real time throughout the imposed strain with an epifluorescent microscopy system. Peak change in [Ca2+]i recovery of [Ca2+]i and percent responding NG108-15 cells were shown to be dependent on strain rate (1(-1) to 10(-1)) and magnitude (0.1 to 0.3 Green's Strain). These measures were also shown to depend significantly on the interaction between strain rate and magnitude. This model for neural trauma is a robust system that can be used to investigate the cellular tolerance and response to traumatic brain injury.

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Robert S. Cargill

Mechanical Stretch to Neurons Results in a Strain Rate and Magnitude-Dependent Increase in Plasma Membrane Permeability

High rate shear strain of three-dimensional neural cell cultures: a new in vitro traumatic brain injury model

Acute Alterations in [Ca²⁺]_iin NG108-15 Cells Subjected to High Strain Rate Deformation and Chemical Hypoxia: Anin VitroModel for Neural Trauma

Susceptibility of hippocampal neurons to mechanically induced injury

An in Vitro Model of Neural Trauma: Device Characterization and Calcium Response to Mechanical Stretch

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About

Robert S. Cargill

Mechanical Stretch to Neurons Results in a Strain Rate and Magnitude-Dependent Increase in Plasma Membrane Permeability

High rate shear strain of three-dimensional neural cell cultures: a new in vitro traumatic brain injury model

Acute Alterations in [Ca2+]iin NG108-15 Cells Subjected to High Strain Rate Deformation and Chemical Hypoxia: Anin VitroModel for Neural Trauma

Susceptibility of hippocampal neurons to mechanically induced injury

An in Vitro Model of Neural Trauma: Device Characterization and Calcium Response to Mechanical Stretch

Contact Info

Product

Resources

About

Acute Alterations in [Ca²⁺]_iin NG108-15 Cells Subjected to High Strain Rate Deformation and Chemical Hypoxia: Anin VitroModel for Neural Trauma