Electrical Stimulation Increases Axonal Growth from Dorsal Root Ganglia Co-Cultured with Schwann Cells in Highly Aligned PLA-PPy-Au Microfiber Substrates

Roca, Fernando Gisbert; Requena, Sara Serrano; Pradas, Manuel Monleón; Martínez‐Ramos, Cristina

doi:10.3390/ijms23126362

Cited by 10 publications

(8 citation statements)

References 102 publications

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“…Interestingly, the in vitro delivery of DHX or BDNF within electrospun PLA fibers follows a similar profile as the PLA-curcumin membrane fibers, with a linear, rapid delivery profile for the first week followed by a slower rate of delivery of the remaining cargo (Liu et al, 2022). We previously demonstrated that PLA nanofibers improved neurite growth and axonal guidance (Gisbert Roca et al, 2020;Gisbert Roca et al, 2021;Gisbert Roca et al, 2022), but as shown here, the addition of curcumin did not display any additive effect. Nevertheless, equivalent concentrations of sustained delivered curcumin from the PLA nanofibers could contribute to neuronal elongation and axonal growth in endogenous tissue; however, this phenomenon will need to be further evaluated in a longer-term study.…”

Section: Discussioncontrasting

confidence: 47%

“…PLA substrates are suitable for NPC transplantation allowing adhesion, planar distribution, proliferation, migration, and differentiation (Li et al, 2021;Li et al, 2022) providing a less invasive transplantation and cell delivery method instead of direct injection into the SCI (Zholudeva and Lane, 2019). We recently demonstrated that these materials improved neurite outgrowth and axonal guidance (Gisbert Roca et al, 2020;Gisbert Roca et al, 2021;Gisbert Roca et al, 2022), making them an ideal candidate for NPC delivery and the repair of neuronal tissue damage. Additionally, our research has shown that delivering NPC in combination with curcumin directly to the injured spinal cord can promote neuroprotection and stimulate axonal growth (Requejo-Aguilar et al, 2017;Bonilla et al, 2021;Elkhenany et al, 2021).…”

Section: Introductionmentioning

confidence: 99%

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Acute transplantation of NPC on electrospun poly-lactic acid membranes containing curcumin into the injured spinal cord reduces neuronal degeneration

Sánchez-Martín,

Giraldo,

Gisbert Roca

et al. 2023

Front. Biomater. Sci.

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Effective spinal cord injury (SCI) treatment remains a significant challenge, given the complex nature of the primary injury and associated devastating loss of neural activity. Neural progenitor cell (NPC)-based therapy has emerged as a potent strategy for the treatment of SCI. However, the invasive nature of direct cell transplantation and the need to enhance graft integration into host tissue remain critical issues. We implemented an improved combinatorial approach to SCI treatment by functionalizing electrospun poly-lactic acid (PLA) membranes that support the sustained delivery of curcumin (PLA-curcumin) and act as a carrier for NPC for local transplantation. In vitro experiments demonstrate that curcumin prevents harmful oxidative and inflammatory stress by preventing death and inhibiting NF-κB activation (mimicked by treatment with hydrogen peroxide or lipopolysaccharide acid). Curcumin also enhances neurite-like outgrowth in NPC and cortical neurons in culture, which may enhance neural connectivity. In vivo transplantation of NPC on a PLA-curcumin electrospun membrane enables cell migration, reduces injured area size, and increases neuronal fiber preservation to induce a slowing of acute neural damage.

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Section: Discussioncontrasting

confidence: 47%

Section: Introductionmentioning

confidence: 99%

Acute transplantation of NPC on electrospun poly-lactic acid membranes containing curcumin into the injured spinal cord reduces neuronal degeneration

Sánchez-Martín,

Giraldo,

Gisbert Roca

et al. 2023

Front. Biomater. Sci.

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“…A clinical study showed that the success rate of nerve conduit alone was more varied and less reliable in such cases [38]. The scaffold-free method could allow researchers to fabricate more complex structures to mimic actual nerves, such as using electrical stimulation to dictate the direction of motor neurons co-cultured with Schwann cells [39]. Our results indicate that early induction of SCAPs towards neural lineage using a small-molecule cocktail is beneficial in promoting sciatic nerve recovery but likely not sufficient for full recovery in the long term.…”

Section: Discussionmentioning

confidence: 99%

Transplantation of Neural Progenitor Cells Derived from Stem Cells from Apical Papilla Through Small-Molecule Induction in a Rat Model of Sciatic Nerve Injury

Koh,

Liu,

Poon

et al. 2024

Tissue Eng Regen Med

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Background: Stem cell-based transplantation therapy holds promise for peripheral nerve injury treatment, but adult availability is limited. A cell culture protocol utilizing a small-molecule cocktail effectively reprogrammed stem cells from apical papilla (SCAPs) into neural progenitor cells, subsequently differentiating into neuron-like cells. This study aims to evaluate neural-induced SCAPs, with and without small-molecule cocktail, for sciatic nerve repair potential. Methods: A scaffold-free cell sheet technique was used to construct a three-dimensional cell sheet. Subsequently, this cell sheet was carefully rolled into a tube and seamlessly inserted into a collagen conduit, which was then transplanted into a 5 mm sciatic nerve injury rat model. Functional sciatic nerve regeneration was evaluated via toe spread test, walking track analysis and gastrocnemius muscle weight. Additionally, degree of sciatic nerve regeneration was determined based on total amount of myelinated fibers. Results: Small-molecule cocktail induced SCAPs enhanced motor function recovery, evident in improved sciatic function index and gastrocnemius muscle retention. We also observed better host myelinated fiber retention than undifferentiated SCAPs or neural-induced SCAPs without small-molecule cocktail. However, clusters of neuron-like cell bodies (surrounded by sparse myelinated fibers) were found in all cell sheet-implanted groups in the implantation region. This suggests that while the implanted cells likely survived transplantation, integration was poor and would likely hinder long-term recovery by occupying the space needed for host nerve fibers to project through. Conclusion: Neural-induced SCAPs with small-molecule cocktail demonstrated promising benefits for nerve repair; further research is needed to improve its integration and optimize its potential for long-term recovery.

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“…However, the migration mechanism of Schwann cells is still unclear, which may be related to calcium gradients by ES, [114] ES-increased neurotrophin secretion, [115] the activation in mitogen-activated protein kinase (MAPK), [116] and so on. Due to the slow growth rate (1 mm per day) of nerve regeneration and the short growth duration (less than 1 year), [117] the existing migration efficiency of Schwann cells is still challenging to span the critical distance (e.g., 3 cm) of peripheral nerve regeneration. The adequate stimulus time, electric field, Schwann cell viability, and regenerative process are Electrical conductivity [42] [S cm 2-100 [42] High-performance capacitor, [43] rescue thrombolysis, [44] conductive scaffold, [45] flexible wearable devices, [46] drug nanocarrier-release system, [47] photothermal-converters, [48] biosensor, [49] osteogenic scaffold, [50] ion adsorption device.…”

Section: Polypyrrolementioning

confidence: 99%

Three Potential Elements of Developing Nerve Guidance Conduit for Peripheral Nerve Regeneration

Zhang,

Gong,

Zhang

et al. 2023

Adv Funct Materials

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Autograft replaced by a nerve guidance conduit (NGC) is challenging in peripheral nerve injury because current NGC is still limited by precise conductivity and excellent biocompatibility in vivo, which influences the peripheral nerve repair even for a long lesion gap repair. Several particular elements have the potential function for nerve conductivity acceleration based on the traditional three factors of neural tissue engineering. The review aims to address three questions: 1) What is the superior factor for nerve conduction in the application? 2) How can a more conductive regenerative scaffold be constructed in vivo? 3) What is the next step in nerve regeneration for NGC? The bibliometrics analysis of NGC‐related references is adopted to acquire that the conductive material, manufacturing technology of neural scaffold, and electrical stimulation (ES) play essential roles in the acceleration of nerve conduction. This review visually analyses the research status and summarizes the main types of conductive materials, the manufacturing technologies of neural scaffolds, and the characteristics of ES. The viewpoints and outlook of developing NGC are also discussed in this review. The proposed three elements are expected to improve the nerve conduction of NGC in vivo and even address the dilemma of long‐distance peripheral nerve injury.

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Electrical Stimulation Increases Axonal Growth from Dorsal Root Ganglia Co-Cultured with Schwann Cells in Highly Aligned PLA-PPy-Au Microfiber Substrates

Cited by 10 publications

References 102 publications

Acute transplantation of NPC on electrospun poly-lactic acid membranes containing curcumin into the injured spinal cord reduces neuronal degeneration

Acute transplantation of NPC on electrospun poly-lactic acid membranes containing curcumin into the injured spinal cord reduces neuronal degeneration

Transplantation of Neural Progenitor Cells Derived from Stem Cells from Apical Papilla Through Small-Molecule Induction in a Rat Model of Sciatic Nerve Injury

Three Potential Elements of Developing Nerve Guidance Conduit for Peripheral Nerve Regeneration

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