Biomaterials to Neuroprotect the Stroke Brain: A Large Opportunity for Narrow Time Windows

González‐Nieto, Daniel; Fernández-Serra, Rocío; Pérez‐Rigueiro, José; Panetsos, Fivos; Martı́nez-Murillo, Ricardo; Guinea, Gustavo V.

doi:10.3390/cells9051074

Cited by 36 publications

(28 citation statements)

References 232 publications

(296 reference statements)

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“…The delivery of drugs to the brain becomes even further challenging in injured brains, e.g., due to a traumatic injury or brain edema, as the result of damage limits the drug diffusion significantly [ 177 ]. Although a breach in the BBB permeability occurs after injury [ 178 ], systemically administered molecules might not necessarily have open access to the brain.…”

Section: Increasing the Performance Of Silk Fibroin In Neural Tissmentioning

confidence: 99%

Silk Fibroin: An Ancient Material for Repairing the Injured Nervous System

et al. 2021

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Silk refers to a family of natural fibers spun by several species of invertebrates such as spiders and silkworms. In particular, silkworm silk, the silk spun by Bombyx mori larvae, has been primarily used in the textile industry and in clinical settings as a main component of sutures for tissue repairing and wound ligation. The biocompatibility, remarkable mechanical performance, controllable degradation, and the possibility of producing silk-based materials in several formats, have laid the basic principles that have triggered and extended the use of this material in regenerative medicine. The field of neural soft tissue engineering is not an exception, as it has taken advantage of the properties of silk to promote neuronal growth and nerve guidance. In addition, silk has notable intrinsic properties and the by-products derived from its degradation show anti-inflammatory and antioxidant properties. Finally, this material can be employed for the controlled release of factors and drugs, as well as for the encapsulation and implantation of exogenous stem and progenitor cells with therapeutic capacity. In this article, we review the state of the art on manufacturing methodologies and properties of fiber-based and non-fiber-based formats, as well as the application of silk-based biomaterials to neuroprotect and regenerate the damaged nervous system. We review previous studies that strategically have used silk to enhance therapeutics dealing with highly prevalent central and peripheral disorders such as stroke, Alzheimer’s disease, Parkinson’s disease, and peripheral trauma. Finally, we discuss previous research focused on the modification of this biomaterial, through biofunctionalization techniques and/or the creation of novel composite formulations, that aim to transform silk, beyond its natural performance, into more efficient silk-based-polymers towards the clinical arena of neuroprotection and regeneration in nervous system diseases.

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Section: Increasing the Performance Of Silk Fibroin In Neural Tissmentioning

confidence: 99%

Silk Fibroin: An Ancient Material for Repairing the Injured Nervous System

et al. 2021

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“…In addition, transient forebrain ischemia increases pro-inflammatory cytokine release from astrocytes and microglia to enhance neuronal damage in the hippocampus [ 8 , 9 ]. Several mechanisms have been proposed for the execution of neuronal damage upon ischemic insult [ 10 , 11 , 12 ]; however, there is a dearth of therapeutic agents owing to their limited ability to cross the blood–brain barrier as well as the cell membrane. To overcome these difficulties, cell-penetrating peptides (CPPs) have been introduced [ 13 ], and one of these CPPs consists of the trans -acting activator of transcription (Tat), originating from the human immunodeficiency virus.…”

Section: Introductionmentioning

confidence: 99%

Tat-Endophilin A1 Fusion Protein Protects Neurons from Ischemic Damage in the Gerbil Hippocampus: A Possible Mechanism of Lipid Peroxidation and Neuroinflammation Mitigation as Well as Synaptic Plasticity

Jung

Kwon

Kim

et al. 2021

Cells

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The present study explored the effects of endophilin A1 (SH3GL2) against oxidative damage brought about by H2O2 in HT22 cells and ischemic damage induced upon transient forebrain ischemia in gerbils. Tat-SH3GL2 and its control protein (Control-SH3GL2) were synthesized to deliver it to the cells by penetrating the cell membrane and blood–brain barrier. Tat-SH3GL2, but not Control-SH3GL2, could be delivered into HT22 cells in a concentration- and time-dependent manner and the hippocampus 8 h after treatment in gerbils. Tat-SH3GL2 was stably present in HT22 cells and degraded with time, by 36 h post treatment. Pre-incubation with Tat-SH3GL2, but not Control-SH3GL2, significantly ameliorated H2O2-induced cell death, DNA fragmentation, and reactive oxygen species formation. SH3GL2 immunoreactivity was decreased in the gerbil hippocampal CA1 region with time after ischemia, but it was maintained in the other regions after ischemia. Tat-SH3GL2 treatment in gerbils appreciably improved ischemia-induced hyperactivity 1 day after ischemia and the percentage of NeuN-immunoreactive surviving cells increased 4 days after ischemia. In addition, Tat-SH3GL2 treatment in gerbils alleviated the increase in lipid peroxidation as assessed by the levels of malondialdehyde and 8-iso-prostaglandin F2α and in pro-inflammatory cytokines such as tumor necrosis factor-α, interleukin-1β, and interleukin-6; while the reduction of protein levels in markers for synaptic plasticity, such as postsynaptic density 95, synaptophysin, and synaptosome associated protein 25 after transient forebrain ischemia was also observed. These results suggest that Tat-SH3GL2 protects neurons from oxidative and ischemic damage by reducing lipid peroxidation and inflammation and improving synaptic plasticity after ischemia.

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“…The development of drug delivery systems may be a key element to achieve successful therapy [ 26 , 27 , 28 ]. The particular advantages of drug delivery systems in brain injury include that (i) blood-brain barrier permeability for a specific drug is substantially increased, (ii) drug delivery can be targeted selectively to sites at risk of injury, (iii) these systems carry the potential of gradual drug release to elongate drug exposure, and (iv) local drug concentration may become high enough to exert therapeutic effect, without the risk of drug accumulation in non-target tissues, which carries the risk of undesirable side effects or off-target toxicity.…”

Section: Introductionmentioning

confidence: 99%

Tissue Acidosis Associated with Ischemic Stroke to Guide Neuroprotective Drug Delivery

Tóth

Menyhárt

Frank

et al. 2020

Biology

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Ischemic stroke is a leading cause of death and disability worldwide. Yet, the effective therapy of focal cerebral ischemia has been an unresolved challenge. We propose here that ischemic tissue acidosis, a sensitive metabolic indicator of injury progression in cerebral ischemia, can be harnessed for the targeted delivery of neuroprotective agents. Ischemic tissue acidosis, which represents the accumulation of lactic acid in malperfused brain tissue is significantly exacerbated by the recurrence of spreading depolarizations. Deepening acidosis itself activates specific ion channels to cause neurotoxic cellular Ca2+ accumulation and cytotoxic edema. These processes are thought to contribute to the loss of the ischemic penumbra. The unique metabolic status of the ischemic penumbra has been exploited to identify the penumbra zone with imaging tools. Importantly, acidosis in the ischemic penumbra may also be used to guide therapeutic intervention. Agents with neuroprotective promise are suggested here to be delivered selectively to the ischemic penumbra with pH-responsive smart nanosystems. The administered nanoparticels release their cargo in acidic tissue environment, which reliably delineates sites at risk of injury. Therefore, tissue pH-targeted drug delivery is expected to enrich sites of ongoing injury with the therapeutical agent, without the risk of unfavorable off-target effects.

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Biomaterials to Neuroprotect the Stroke Brain: A Large Opportunity for Narrow Time Windows

Cited by 36 publications

References 232 publications

Silk Fibroin: An Ancient Material for Repairing the Injured Nervous System

Silk Fibroin: An Ancient Material for Repairing the Injured Nervous System

Tat-Endophilin A1 Fusion Protein Protects Neurons from Ischemic Damage in the Gerbil Hippocampus: A Possible Mechanism of Lipid Peroxidation and Neuroinflammation Mitigation as Well as Synaptic Plasticity

Tissue Acidosis Associated with Ischemic Stroke to Guide Neuroprotective Drug Delivery

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