Impact of simulated brain interstitial fluid flow on the chemokine CXCL12 release from an alginate-based hydrogel in a new 3D in vitro model

Kheir, Wiam El; Dumais, Alexandre; Beaudoin, Maude; Marcos, Bernard; Virgilio, Nick; Paquette, Benoît; Faucheux, Nathalie; Lauzon, Marc-Antoine

doi:10.3389/fddev.2023.1227776

Cited by 2 publications

(1 citation statement)

References 43 publications

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“…The +Flow group received reopening of injury, puncturing of the cavity, and delivery of sterile saline at 1 µL/min (approximately three times the normal interstitial flow rate). 45,46 Both groups were re-sutured and kept in their home cage for an additional 3 days. Ketoprofen (1 mg/kg, Zoetic©) was administered subcutaneously for 48 hours after the CED.…”

Section: Animal Proceduresmentioning

confidence: 99%

Convective forces contribute to post-traumatic degeneration after spinal cord injury

Kwon,

Streilein,

Chase Cornelison

2024

Preprint

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Spinal cord injury (SCI) initiates a complex cascade of chemical and biophysical phenomena that result in tissue swelling, progressive neural degeneration, and formation of a fluid-filled cavity. Previous studies show fluid pressure above the spinal cord (supraspinal) is elevated for at least three days after injury and contributes to a phase of damage called secondary injury. Currently, it is unknown how fluid forces within the spinal cord itself (interstitial) are affected by SCI and if they contribute to secondary injury. We find spinal interstitial pressure increases from -3 mmHg in the naive cord to a peak of 13 mmHg at 3 days post-injury (DPI) but relatively normalizes to 2 mmHg by 7 DPI. A computational fluid dynamics model predicts interstitial flow velocities up to 0.9 μm/s at 3 DPI, returning to near baseline by 7 DPI. By quantifying vascular leakage of Evans Blue dye after a cervical hemi-contusion in rats, we confirm an increase in dye infiltration at 3 DPI compared to 7 DPI, suggestive of higher fluid velocities at the time of peak fluid pressure.In vivoexpression of the apoptosis marker caspase-3 is strongly correlated with regions of interstitial flow at 3 DPI, and exogenously enhancing interstitial flow exacerbates tissue damage.In vitro, we show overnight exposure of neuronal cells to low pathological shear stress (0.1 dynes/cm2) significantly reduces cell count and neurite length. Collectively, these results indicate that interstitial fluid flow and shear stress may play a detrimental role in post-traumatic neural degeneration.Translational Impact StatementTrauma to the central nervous system induces neural tissue degeneration, resulting in permanent disability and loss of function. A better understanding of this degenerative process is needed, towards developing new clinical treatments that effectively minimize tissue damage and preserve neural function after injury. The present study identifies a potential role for altered fluid transport within the injured spinal cord. These results provide new insight into basic pathophysiology and may inform therapeutic development for neuroprotection.

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Section: Animal Proceduresmentioning

confidence: 99%

Convective forces contribute to post-traumatic degeneration after spinal cord injury

Kwon,

Streilein,

Chase Cornelison

2024

Preprint

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Dynamic three-dimensional coculture model: The future of tissue engineering applied to the peripheral nervous system

Choinière,

Petit,

Monfette

et al. 2024

J Tissue Eng

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Traumatic injuries to the peripheral nervous system (PNI) can lead to severe consequences such as paralysis. Unfortunately, current treatments rarely allow for satisfactory functional recovery. The high healthcare costs associated with PNS injuries, worker disability, and low patient satisfaction press for alternative solutions that surpass current standards. For the treatment of injuries with a deficit of less than 30 mm to bridge, the use of synthetic nerve conduits (NGC) is favored. However, to develop such promising therapeutic strategies, in vitro models that more faithfully mimic nerve physiology are needed. The absence of a clinically scaled model with essential elements such as a three-dimension environment and dynamic coculture has hindered progress in this field. The presented research focuses on the development of an in vitro coculture model of the peripheral nervous system (PNS) involving the use of functional biomaterial which microstructure replicates nerve topography. Initially, the behavior of neuron-derived cell lines (N) and Schwann cells (SC) in contact with a short section of biomaterial (5 mm) was studied. Subsequent investigations, using fluorescent markers and survival assays, demonstrated the synergistic effects of coculture. These optimized parameters were then applied to longer biomaterials (30 mm), equivalent to clinically used NGC. The results obtained demonstrated the possibility of maintaining an extended coculture of SC and N over a 7-day period on a clinically scaled biomaterial, observing some functionality. In the long term, the knowledge gained from this work will contribute to a better understanding of the PNS regeneration process and promote the development of future therapeutic approaches while reducing reliance on animal experimentation. This model can be used for drug screening and adapted for personalized medicine trials. Ultimately, this work fills a critical gap in current research, providing a transformative approach to study and advance treatments for PNS injuries.

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Impact of simulated brain interstitial fluid flow on the chemokine CXCL12 release from an alginate-based hydrogel in a new 3D in vitro model

Cited by 2 publications

References 43 publications

Convective forces contribute to post-traumatic degeneration after spinal cord injury

Convective forces contribute to post-traumatic degeneration after spinal cord injury

Dynamic three-dimensional coculture model: The future of tissue engineering applied to the peripheral nervous system

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