Publications by authors named "Bingkun K Chen"

The spinal cord has a poor ability to regenerate after an injury, which may be due to cell loss, cyst formation, inflammation, and scarring. A promising approach to treating a spinal cord injury (SCI) is the use of biomaterials. We have developed a novel hydrogel scaffold fabricated from oligo(poly(ethylene glycol) fumarate) (OPF) as a 0.

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Article Synopsis
  • - The study investigates how newly regenerated axons using scaffolds and epidural electrical stimulation (EES) can improve spinal cord circuitry and motor functions after spinal cord injury (SCI).
  • - Over 7 weeks, treatments combining scaffolds with neurotrophin-producing Schwann cells and EES led to significant motor function recovery compared to using scaffolds or EES alone, even though the number of regenerated axons was similar across groups.
  • - When researchers re-transected the spinal cord at week 6, motor performance still exceeded that of other groups, indicating that the combined therapies promote synaptic reorganization and enhanced motor recovery after SCI.
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Study Design: Animal study.

Objectives: Umbilical cord-derived mesenchymal stem cells (UC-MSCs) have recently been shown to hold great therapeutic potential for spinal cord injury (SCI). However, majority of the studies have been done using human cells transplanted into the rat with immunosuppression; this may not represent the outcomes that occur in humans.

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Article Synopsis
  • Neuromodulation technologies show promise in improving motor functions after spinal cord injury (SCI) by enhancing excitability in the spinal networks below the injury site, independent of brain signals.
  • The review assesses how spinal circuits can adapt and reorganize when sensory inputs are present during motor training, leading to potential recovery mechanisms.
  • The implications of these findings suggest that future advancements in neuromodulation and rehabilitation can significantly benefit functional recovery, including the development of neuroprosthetics.
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Hydrogel scaffolds provide a beneficial microenvironment in transected rat spinal cord. A combinatorial biomaterials-based strategy provided a microenvironment that facilitated regeneration while reducing foreign body reaction to the three-dimensional spinal cord construct. We used poly lactic-co-glycolic acid microspheres to provide sustained release of rapamycin from Schwann cell (SC)-loaded, positively charged oligo-polyethylene glycol fumarate scaffolds.

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Positively-charged oligo[poly(ethylene glycol)fumarate] (OPF ) is a biodegradable hydrogel used for spinal cord injury repair. We compared scaffolds containing primary Schwann cells (SCs) to scaffolds delivering SCs genetically modified to secrete high concentrations of glial cell-derived neurotrophic factor (GDNF). Multichannel OPF scaffolds loaded with SCs or GDNF-SCs were implanted into transected rat spinal cords for 4 weeks.

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Positively charged oligo[poly(ethylene glycol) fumarate] (OPF+) scaffolds loaded with Schwann cells bridge spinal cord injury (SCI) lesions and support axonal regeneration in rat. The regeneration achieved is not sufficient for inducing functional recovery. Attempts to increase regeneration would benefit from understanding the effects of the scaffold and transplanted cells on lesion environment.

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Background: There are no effective treatments that slow the progression of neurodegenerative diseases. A major challenge of treatment in neurodegenerative diseases is appropriate delivery of pharmaceuticals into the cerebrospinal fluid (CSF) of affected individuals. Mesenchymal stromal cells (MSCs-either naïve or modified) are a promising therapy in neurodegenerative diseases and may be delivered directly into the CSF where they can reside for months.

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The use of multichannel polymer scaffolds in a complete spinal cord transection injury serves as a deconstructed model that allows for control of individual variables and direct observation of their effects on regeneration. In this study, scaffolds fabricated from positively charged oligo[poly(ethylene glycol)fumarate] (OPF(+)) hydrogel were implanted into rat spinal cords following T9 complete transection. OPF(+) scaffold channels were loaded with either syngeneic Schwann cells or mesenchymal stem cells derived from enhanced green fluorescent protein transgenic rats (eGFP-MSCs).

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Background Context: Traumatic injuries occurring at the conus medullaris of the spinal cord cause permanent damage both to the central nervous system and to the cauda equina nerve roots.

Purpose: This proof-of-concept study was to determine whether implanting the nerve roots into a biodegradable scaffold would improve regeneration after injury.

Methods: All experimental works involving rats were performed according to the approved guidelines by the Mayo Clinic Institutional Animal Care and Use Committee.

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Techniques used to produce partial spinal cord injuries in animal models have the potential for creating variability in lesions. The amount of tissue affected may influence the functional outcomes assessed in the animals. The recording of somatosensory evoked potentials (SSEPs) may be a valuable tool for assessing the extent of lesion applied in animal models of traumatic spinal cord injury (SCI).

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Article Synopsis
  • The study uses a rat spinal cord model to compare different biodegradable polymer scaffolds for their effectiveness in promoting nerve regeneration after spinal cord injury.
  • Various scaffolds, including Schwann cell-loaded OPF and PCLF, showed promising mechanical properties similar to the rat spinal cord and supported axonal growth.
  • PCLF and OPF+ resulted in significantly more axonal regeneration compared to PLGA, with OPF+ showing superior central axonal distribution and smaller cyst volumes compared to PLGA, indicating potential for improved strategies in tissue engineering.
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We have characterized a method of labeling of axons in the post-mortem spinal cord using a silastic disc holding pins coated with DiI and DiO at the rostral and caudal ends of the cord. We optimized the DiI and DiO tracing techniques under different conditions of fixative concentration (1% versus 4% paraformaldehyde, PF), at room temperature (RT) versus 37 degrees C for up to 24 weeks. Crystal coated pins embedded in a silastic disc provided a novel method of dye application.

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