Epidural oscillating field stimulation as an effective therapeutic approach in combination therapy for spinal cord injury

•Epidural implantation of oscillating field (OF) stimulator after Th9 SCI in rats.•OF stimulation improves axon regeneration and reduces astrogliosis after SCI.•Promising method for combination SCI therapy in future studies. Traumatic spinal cord injury (SCI) causes partial or total loss of sensory...

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Published inJournal of neuroscience methods Vol. 311; pp. 102 - 110
Main Authors Bacova, Maria, Bimbova, Katarina, Fedorova, Jana, Lukacova, Nadezda, Galik, Jan
Format Journal Article
LanguageEnglish
Published Netherlands Elsevier B.V 01.01.2019
Subjects
Animals
Astrocytes - pathology
Disease Models, Animal
Electric Stimulation Therapy - instrumentation
Electric Stimulation Therapy - methods
Electrodes, Implanted
Female
Functional outcome
Intermediate Filaments - pathology
Nerve Regeneration
Neurofilaments
Oscillating field stimulation
Rats, Wistar
Reduction of astrogliosis
Spared white matter
Spinal Cord - pathology
Spinal Cord - physiopathology
Spinal Cord Injuries - pathology
Spinal Cord Injuries - physiopathology
Spinal Cord Injuries - therapy
Spinal Th9 compression
Treatment Outcome
Neurofilaments
Reduction of astrogliosis
Spared white matter
Oscillating field stimulation
Spinal Th9 compression
Functional outcome
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Abstract •Epidural implantation of oscillating field (OF) stimulator after Th9 SCI in rats.•OF stimulation improves axon regeneration and reduces astrogliosis after SCI.•Promising method for combination SCI therapy in future studies. Traumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective treatment which might improve patients’ neurological status.The application of electric current to the injured spinal cord is known to promote healing and tissue regeneration. The use of this modality in treating the injured spinal cord to improve neurological recovery has been introduced as a potential treatment. Here we describe the method of epidural implantation of a miniature oscillating field (OF) stimulator designed in our laboratory immediately after Th9 spinal compression in Wistar rats. Three groups of animals were analyzed (intact; SCI only; OFS + SCI; n = 8 each). Histological, immunohistological and behavioral analysis were used to show the favorable effect of epidural OF stimulation on axonal regeneration and modulation of astrogliosis. Our study revealed considerable differences in white matter integrity in animals with an implanted OF stimulator. Moreover, we detected significantly increased numbers of neurofilaments and massive reduction in activated forms of astrocytes in the group of stimulated animals compared to the animals without stimulation. Compared with previous research, our study revealed that epidural implantation of an OF stimulator immediately after spinal compression effectively reduced the expression of inflammatory response and suppressed activated astrocyte formation. Our finding confirms that implanting an OF stimulator is safe, stable and suitable for future combined therapy which could effectively promote and accelerate regeneration and functional restoration after spinal trauma.
AbstractList •Epidural implantation of oscillating field (OF) stimulator after Th9 SCI in rats.•OF stimulation improves axon regeneration and reduces astrogliosis after SCI.•Promising method for combination SCI therapy in future studies. Traumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective treatment which might improve patients’ neurological status.The application of electric current to the injured spinal cord is known to promote healing and tissue regeneration. The use of this modality in treating the injured spinal cord to improve neurological recovery has been introduced as a potential treatment. Here we describe the method of epidural implantation of a miniature oscillating field (OF) stimulator designed in our laboratory immediately after Th9 spinal compression in Wistar rats. Three groups of animals were analyzed (intact; SCI only; OFS + SCI; n = 8 each). Histological, immunohistological and behavioral analysis were used to show the favorable effect of epidural OF stimulation on axonal regeneration and modulation of astrogliosis. Our study revealed considerable differences in white matter integrity in animals with an implanted OF stimulator. Moreover, we detected significantly increased numbers of neurofilaments and massive reduction in activated forms of astrocytes in the group of stimulated animals compared to the animals without stimulation. Compared with previous research, our study revealed that epidural implantation of an OF stimulator immediately after spinal compression effectively reduced the expression of inflammatory response and suppressed activated astrocyte formation. Our finding confirms that implanting an OF stimulator is safe, stable and suitable for future combined therapy which could effectively promote and accelerate regeneration and functional restoration after spinal trauma.
Traumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective treatment which might improve patients' neurological status.The application of electric current to the injured spinal cord is known to promote healing and tissue regeneration. The use of this modality in treating the injured spinal cord to improve neurological recovery has been introduced as a potential treatment. Here we describe the method of epidural implantation of a miniature oscillating field (OF) stimulator designed in our laboratory immediately after Th9 spinal compression in Wistar rats. Three groups of animals were analyzed (intact; SCI only; OFS + SCI; n = 8 each). Histological, immunohistological and behavioral analysis were used to show the favorable effect of epidural OF stimulation on axonal regeneration and modulation of astrogliosis. Our study revealed considerable differences in white matter integrity in animals with an implanted OF stimulator. Moreover, we detected significantly increased numbers of neurofilaments and massive reduction in activated forms of astrocytes in the group of stimulated animals compared to the animals without stimulation. Compared with previous research, our study revealed that epidural implantation of an OF stimulator immediately after spinal compression effectively reduced the expression of inflammatory response and suppressed activated astrocyte formation. Our finding confirms that implanting an OF stimulator is safe, stable and suitable for future combined therapy which could effectively promote and accelerate regeneration and functional restoration after spinal trauma.
BACKGROUNDTraumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective treatment which might improve patients' neurological status.The application of electric current to the injured spinal cord is known to promote healing and tissue regeneration. The use of this modality in treating the injured spinal cord to improve neurological recovery has been introduced as a potential treatment. NEW METHODHere we describe the method of epidural implantation of a miniature oscillating field (OF) stimulator designed in our laboratory immediately after Th9 spinal compression in Wistar rats. Three groups of animals were analyzed (intact; SCI only; OFS + SCI; n = 8 each). Histological, immunohistological and behavioral analysis were used to show the favorable effect of epidural OF stimulation on axonal regeneration and modulation of astrogliosis. RESULTSOur study revealed considerable differences in white matter integrity in animals with an implanted OF stimulator. Moreover, we detected significantly increased numbers of neurofilaments and massive reduction in activated forms of astrocytes in the group of stimulated animals compared to the animals without stimulation. COMPARISON WITH EXISTING METHOD(S)Compared with previous research, our study revealed that epidural implantation of an OF stimulator immediately after spinal compression effectively reduced the expression of inflammatory response and suppressed activated astrocyte formation. CONCLUSIONSOur finding confirms that implanting an OF stimulator is safe, stable and suitable for future combined therapy which could effectively promote and accelerate regeneration and functional restoration after spinal trauma.
Author Bacova, Maria
Bimbova, Katarina
Lukacova, Nadezda
Galik, Jan
Fedorova, Jana
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Keywords Neurofilaments
Reduction of astrogliosis
Spared white matter
Oscillating field stimulation
Spinal Th9 compression
Functional outcome
Language English
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Snippet •Epidural implantation of oscillating field (OF) stimulator after Th9 SCI in rats.•OF stimulation improves axon regeneration and reduces astrogliosis after...
Traumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective treatment...
BACKGROUNDTraumatic spinal cord injury (SCI) causes partial or total loss of sensory and motor functions. Despite enormous efforts, there is still no effective...
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SubjectTerms Animals
Astrocytes - pathology
Disease Models, Animal
Electric Stimulation Therapy - instrumentation
Electric Stimulation Therapy - methods
Electrodes, Implanted
Female
Functional outcome
Intermediate Filaments - pathology
Nerve Regeneration
Neurofilaments
Oscillating field stimulation
Rats, Wistar
Reduction of astrogliosis
Spared white matter
Spinal Cord - pathology
Spinal Cord - physiopathology
Spinal Cord Injuries - pathology
Spinal Cord Injuries - physiopathology
Spinal Cord Injuries - therapy
Spinal Th9 compression
Treatment Outcome
Title Epidural oscillating field stimulation as an effective therapeutic approach in combination therapy for spinal cord injury
URI https://dx.doi.org/10.1016/j.jneumeth.2018.10.020
https://www.ncbi.nlm.nih.gov/pubmed/30339879
https://search.proquest.com/docview/2123720562
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