Andrew R. Stevens, Mohammed Hadis, Alice Phillips, Abhinav Thareja, Michael Milward, Antonio Belli, William Palin, David J. Davies, Zubair Ahmed
{"title":"植入式和经皮光生物调制促进脊髓损伤后的神经再生和丧失功能的恢复","authors":"Andrew R. Stevens, Mohammed Hadis, Alice Phillips, Abhinav Thareja, Michael Milward, Antonio Belli, William Palin, David J. Davies, Zubair Ahmed","doi":"10.1002/btm2.10674","DOIUrl":null,"url":null,"abstract":"<p>Spinal cord injury (SCI) is a cause of profound and irreversible damage, with no effective therapy to promote functional recovery. Photobiomodulation (PBM) may provide a viable therapeutic approach using red or near-infrared light to promote recovery after SCI by mitigating neuroinflammation and preventing neuronal apoptosis. Our current study aimed to optimize PBM dose regimens and develop and validate the efficacy of an invasive PBM delivery paradigm for SCI. Dose optimization studies were performed using a serum withdrawal model of injury in cultures of primary adult rat dorsal root ganglion neurons (DRGN). Implantable and transcutaneous PBM delivery protocols were developed and validated using cadaveric modeling. The efficacy of PBM in promoting recovery after SCI in vivo was studied in a dorsal column crush injury model of SCI in adult rats. Optimal neuroprotection in vitro was achieved between 4 and 22 mW/cm<sup>2</sup>. 11 mW/cm<sup>2</sup> for 1 min per day (0.66 J/cm<sup>2</sup>) increased cell viability by 45% over 5 days (<i>p</i> <0.0001), increasing neurite outgrowth by 25% (<i>p</i> <0.01). A method for invasive application of PBM was developed using a diffusion-tipped optogenetics fiber optic. Delivery methods for PBM were developed and validated for both invasive (iPBM) and noninvasive (transcutaneous) (tcPBM) application. iPBM and tcPBM (24 mW/cm<sup>2</sup> at spinal cord, 1 min per day (1.44 J/cm<sup>2</sup>) up to 7 days) increased activation of regeneration-associated protein at 3 days after SCI, increasing GAP43<sup>+</sup> axons in DRGN from 18.0% (control) to 41.4% ± 10.5 (iPBM) and 45.8% ± 3.4 (tcPBM) (<i>p</i> <0.05). This corresponded to significant improvements at 6 weeks post-injury in functional locomotor and sensory function recovery (<i>p</i> <0.01), axonal regeneration (<i>p</i> <0.01), and reduced lesion size (<i>p</i> <0.01). Our results demonstrated that PBM achieved a significant therapeutic benefit after SCI, either using iPBM or tcPBM application and can potentially be developed for clinical use in SCI patients.</p>","PeriodicalId":9263,"journal":{"name":"Bioengineering & Translational Medicine","volume":"9 6","pages":""},"PeriodicalIF":6.1000,"publicationDate":"2024-04-25","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://onlinelibrary.wiley.com/doi/epdf/10.1002/btm2.10674","citationCount":"0","resultStr":"{\"title\":\"Implantable and transcutaneous photobiomodulation promote neuroregeneration and recovery of lost function after spinal cord injury\",\"authors\":\"Andrew R. Stevens, Mohammed Hadis, Alice Phillips, Abhinav Thareja, Michael Milward, Antonio Belli, William Palin, David J. Davies, Zubair Ahmed\",\"doi\":\"10.1002/btm2.10674\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p>Spinal cord injury (SCI) is a cause of profound and irreversible damage, with no effective therapy to promote functional recovery. Photobiomodulation (PBM) may provide a viable therapeutic approach using red or near-infrared light to promote recovery after SCI by mitigating neuroinflammation and preventing neuronal apoptosis. Our current study aimed to optimize PBM dose regimens and develop and validate the efficacy of an invasive PBM delivery paradigm for SCI. Dose optimization studies were performed using a serum withdrawal model of injury in cultures of primary adult rat dorsal root ganglion neurons (DRGN). Implantable and transcutaneous PBM delivery protocols were developed and validated using cadaveric modeling. The efficacy of PBM in promoting recovery after SCI in vivo was studied in a dorsal column crush injury model of SCI in adult rats. Optimal neuroprotection in vitro was achieved between 4 and 22 mW/cm<sup>2</sup>. 11 mW/cm<sup>2</sup> for 1 min per day (0.66 J/cm<sup>2</sup>) increased cell viability by 45% over 5 days (<i>p</i> <0.0001), increasing neurite outgrowth by 25% (<i>p</i> <0.01). A method for invasive application of PBM was developed using a diffusion-tipped optogenetics fiber optic. Delivery methods for PBM were developed and validated for both invasive (iPBM) and noninvasive (transcutaneous) (tcPBM) application. iPBM and tcPBM (24 mW/cm<sup>2</sup> at spinal cord, 1 min per day (1.44 J/cm<sup>2</sup>) up to 7 days) increased activation of regeneration-associated protein at 3 days after SCI, increasing GAP43<sup>+</sup> axons in DRGN from 18.0% (control) to 41.4% ± 10.5 (iPBM) and 45.8% ± 3.4 (tcPBM) (<i>p</i> <0.05). This corresponded to significant improvements at 6 weeks post-injury in functional locomotor and sensory function recovery (<i>p</i> <0.01), axonal regeneration (<i>p</i> <0.01), and reduced lesion size (<i>p</i> <0.01). 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Implantable and transcutaneous photobiomodulation promote neuroregeneration and recovery of lost function after spinal cord injury
Spinal cord injury (SCI) is a cause of profound and irreversible damage, with no effective therapy to promote functional recovery. Photobiomodulation (PBM) may provide a viable therapeutic approach using red or near-infrared light to promote recovery after SCI by mitigating neuroinflammation and preventing neuronal apoptosis. Our current study aimed to optimize PBM dose regimens and develop and validate the efficacy of an invasive PBM delivery paradigm for SCI. Dose optimization studies were performed using a serum withdrawal model of injury in cultures of primary adult rat dorsal root ganglion neurons (DRGN). Implantable and transcutaneous PBM delivery protocols were developed and validated using cadaveric modeling. The efficacy of PBM in promoting recovery after SCI in vivo was studied in a dorsal column crush injury model of SCI in adult rats. Optimal neuroprotection in vitro was achieved between 4 and 22 mW/cm2. 11 mW/cm2 for 1 min per day (0.66 J/cm2) increased cell viability by 45% over 5 days (p <0.0001), increasing neurite outgrowth by 25% (p <0.01). A method for invasive application of PBM was developed using a diffusion-tipped optogenetics fiber optic. Delivery methods for PBM were developed and validated for both invasive (iPBM) and noninvasive (transcutaneous) (tcPBM) application. iPBM and tcPBM (24 mW/cm2 at spinal cord, 1 min per day (1.44 J/cm2) up to 7 days) increased activation of regeneration-associated protein at 3 days after SCI, increasing GAP43+ axons in DRGN from 18.0% (control) to 41.4% ± 10.5 (iPBM) and 45.8% ± 3.4 (tcPBM) (p <0.05). This corresponded to significant improvements at 6 weeks post-injury in functional locomotor and sensory function recovery (p <0.01), axonal regeneration (p <0.01), and reduced lesion size (p <0.01). Our results demonstrated that PBM achieved a significant therapeutic benefit after SCI, either using iPBM or tcPBM application and can potentially be developed for clinical use in SCI patients.
期刊介绍:
Bioengineering & Translational Medicine, an official, peer-reviewed online open-access journal of the American Institute of Chemical Engineers (AIChE) and the Society for Biological Engineering (SBE), focuses on how chemical and biological engineering approaches drive innovative technologies and solutions that impact clinical practice and commercial healthcare products.