Your search keyword '"Shea, Lonnie D."' showing total 37 results

1. Lentiviral Interleukin-10 Gene Therapy Preserves Fine Motor Circuitry and Function After a Cervical Spinal Cord Injury in Male and Female Mice.

Author

Chen, Jessica Y, Chen, Jessica Y, Fu, Emily J, Patel, Paras R, Hostetler, Alexander J, Sawan, Hasan A, Moss, Kayla A, Hocevar, Sarah E, Anderson, Aileen J, Chestek, Cynthia A, Shea, Lonnie D, Chen, Jessica Y, Chen, Jessica Y, Fu, Emily J, Patel, Paras R, Hostetler, Alexander J, Sawan, Hasan A, Moss, Kayla A, Hocevar, Sarah E, Anderson, Aileen J, Chestek, Cynthia A, and Shea, Lonnie D

Abstract

In mammals, spinal cord injuries often result in muscle paralysis through the apoptosis of lower motor neurons and denervation of neuromuscular junctions. Previous research shows that the inflammatory response to a spinal cord injury can cause additional tissue damage after the initial trauma. To modulate this inflammatory response, we delivered lentiviral anti-inflammatory interleukin-10, via loading onto an implantable biomaterial scaffold, into a left-sided hemisection at the C5 vertebra in mice. We hypothesized that improved behavioral outcomes associated with anti-inflammatory treatment are due to the sparing of fine motor circuit components. We examined behavioral recovery using a ladder beam, tissue sparing using histology, and electromyogram recordings using intraspinal optogenetic stimulation at 2 weeks post-injury. Ladder beam analysis shows interleukin-10 treatment results in significant improvement of behavioral recovery at 2 and 12 weeks post-injury when compared to mice treated with a control virus. Histology shows interleukin-10 results in greater numbers of lower motor neurons, axons, and muscle innervation at 2 weeks post-injury. Furthermore, electromyogram recordings suggest that interleukin-10-treated animals have signal-to-noise ratios and peak-to-peak amplitudes more similar to that of uninjured controls than to that of control injured animals at 2 weeks post-injury. These data show that gene therapy using anti-inflammatory interleukin-10 can significantly reduce tissue damage and subsequent motor deficits after a spinal cord injury. Together, these results suggest that early modulation of the injury response can preserve muscle function with long-lasting benefits.

Published

2021

2. Polycistronic Delivery of IL-10 and NT-3 Promotes Oligodendrocyte Myelination and Functional Recovery in a Mouse Spinal Cord Injury Model.

Author

Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Park, Jonghyuck, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Park, Jonghyuck, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

One million estimated cases of spinal cord injury (SCI) have been reported in the United States and repairing an injury has constituted a difficult clinical challenge. The complex, dynamic, inhibitory microenvironment postinjury, which is characterized by proinflammatory signaling from invading leukocytes and lack of sufficient factors that promote axonal survival and elongation, limits regeneration. Herein, we investigated the delivery of polycistronic vectors, which have the potential to coexpress factors that target distinct barriers to regeneration, from a multiple channel poly(lactide-co-glycolide) (PLG) bridge to enhance spinal cord regeneration. In this study, we investigated polycistronic delivery of IL-10 that targets proinflammatory signaling, and NT-3 that targets axonal survival and elongation. A significant increase was observed in the density of regenerative macrophages for IL-10+NT-3 condition relative to conditions without IL-10. Furthermore, combined delivery of IL-10+NT-3 produced a significant increase of axonal density and notably myelinated axons compared with all other conditions. A significant increase in functional recovery was observed for IL-10+NT-3 delivery at 12 weeks postinjury that was positively correlated to oligodendrocyte myelinated axon density, suggesting oligodendrocyte-mediated myelination as an important target to improve functional recovery. These results further support the use of multiple channel PLG bridges as a growth supportive substrate and platform to deliver bioactive agents to modulate the SCI microenvironment and promote regeneration and functional recovery. Impact statement Spinal cord injury (SCI) results in a complex microenvironment that contains multiple barriers to regeneration and functional recovery. Multiple factors are necessary to address these barriers to regeneration, and polycistronic lentiviral gene therapy represents a strategy to locally express multiple factors simultaneously. A bicistronic vector e

Published

2020

3. Polycistronic Delivery of IL-10 and NT-3 Promotes Oligodendrocyte Myelination and Functional Recovery in a Mouse Spinal Cord Injury Model.

Author

Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Park, Jonghyuck, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Park, Jonghyuck, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

One million estimated cases of spinal cord injury (SCI) have been reported in the United States and repairing an injury has constituted a difficult clinical challenge. The complex, dynamic, inhibitory microenvironment postinjury, which is characterized by proinflammatory signaling from invading leukocytes and lack of sufficient factors that promote axonal survival and elongation, limits regeneration. Herein, we investigated the delivery of polycistronic vectors, which have the potential to coexpress factors that target distinct barriers to regeneration, from a multiple channel poly(lactide-co-glycolide) (PLG) bridge to enhance spinal cord regeneration. In this study, we investigated polycistronic delivery of IL-10 that targets proinflammatory signaling, and NT-3 that targets axonal survival and elongation. A significant increase was observed in the density of regenerative macrophages for IL-10+NT-3 condition relative to conditions without IL-10. Furthermore, combined delivery of IL-10+NT-3 produced a significant increase of axonal density and notably myelinated axons compared with all other conditions. A significant increase in functional recovery was observed for IL-10+NT-3 delivery at 12 weeks postinjury that was positively correlated to oligodendrocyte myelinated axon density, suggesting oligodendrocyte-mediated myelination as an important target to improve functional recovery. These results further support the use of multiple channel PLG bridges as a growth supportive substrate and platform to deliver bioactive agents to modulate the SCI microenvironment and promote regeneration and functional recovery. Impact statement Spinal cord injury (SCI) results in a complex microenvironment that contains multiple barriers to regeneration and functional recovery. Multiple factors are necessary to address these barriers to regeneration, and polycistronic lentiviral gene therapy represents a strategy to locally express multiple factors simultaneously. A bicistronic vector e

Published

2020

4. Aligned hydrogel tubes guide regeneration following spinal cord injury.

Author

Dumont, Courtney M, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Ciciriello, Andrew J, Strnadova, Katerina, Park, Jonghyuck, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Dumont, Courtney M, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Ciciriello, Andrew J, Strnadova, Katerina, Park, Jonghyuck, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Directing the organization of cells into a tissue with defined architectures is one use of biomaterials for regenerative medicine. To this end, hydrogels are widely investigated as they have mechanical properties similar to native soft tissues and can be formed in situ to conform to a defect. Herein, we describe the development of porous hydrogel tubes fabricated through a two-step polymerization process with an intermediate microsphere phase that provides macroscale porosity (66.5%) for cell infiltration. These tubes were investigated in a spinal cord injury model, with the tubes assembled to conform to the injury and to provide an orientation that guides axons through the injury. Implanted tubes had good apposition and were integrated with the host tissue due to cell infiltration, with a transient increase in immune cell infiltration at 1 week that resolved by 2 weeks post injury compared to a gelfoam control. The glial scar was significantly reduced relative to control, which enabled robust axon growth along the inner and outer surface of the tubes. Axon density within the hydrogel tubes (1744 axons/mm2) was significantly increased more than 3-fold compared to the control (456 axons/mm2), with approximately 30% of axons within the tube myelinated. Furthermore, implantation of hydrogel tubes enhanced functional recovery relative to control. This modular assembly of porous tubes to fill a defect and directionally orient tissue growth could be extended beyond spinal cord injury to other tissues, such as vascular or musculoskeletal tissue. STATEMENT OF SIGNIFICANCE: Tissue engineering approaches that mimic the native architecture of healthy tissue are needed following injury. Traditionally, pre-molded scaffolds have been implemented but require a priori knowledge of wound geometries. Conversely, hydrogels can conform to any injury, but do not guide bi-directional regeneration. In this work, we investigate the feasibility of a system of modular hydrogel tubes to promo

Published

2019

5. Intravascular innate immune cells reprogrammed via intravenous nanoparticles to promote functional recovery after spinal cord injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Zhang, Yining, Saito, Eiji, Gurczynski, Steve J, Moore, Bethany B, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Zhang, Yining, Saito, Eiji, Gurczynski, Steve J, Moore, Bethany B, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Traumatic primary spinal cord injury (SCI) results in paralysis below the level of injury and is associated with infiltration of hematogenous innate immune cells into the injured cord. Methylprednisolone has been applied to reduce inflammation following SCI, yet was discontinued due to an unfavorable risk-benefit ratio associated with off-target effects. In this study, i.v. administered poly(lactide-coglycolide) nanoparticles were internalized by circulating monocytes and neutrophils, reprogramming these cells based on their physicochemical properties and not by an active pharmaceutical ingredient, to exhibit altered biodistribution, gene expression, and function. Approximately 80% of nanoparticle-positive immune cells were observed within the injury, and, additionally, the overall accumulation of innate immune cells at the injury was reduced 4-fold, coinciding with down-regulated expression of proinflammatory factors and increased expression of antiinflammatory and proregenerative genes. Furthermore, nanoparticle administration induced macrophage polarization toward proregenerative phenotypes at the injury and markedly reduced both fibrotic and gliotic scarring 3-fold. Moreover, nanoparticle administration with the implanted multichannel bridge led to increased numbers of regenerating axons, increased myelination with about 40% of axons myelinated, and an enhanced locomotor function (score of 6 versus 3 for control group). These data demonstrate that nanoparticles provide a platform that limits acute inflammation and tissue destruction, at a favorable risk-benefit ratio, leading to a proregenerative microenvironment that supports regeneration and functional recovery. These particles may have applications to trauma and potentially other inflammatory diseases.

Published

2019

6. PLG Bridge Implantation in Chronic SCI Promotes Axonal Elongation and Myelination.

Author

Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Munsell, Mary K, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Munsell, Mary K, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) is a devastating condition that may cause permanent functional loss below the level of injury, including paralysis and loss of bladder, bowel, and sexual function. Patients are rarely treated immediately, and this delay is associated with tissue loss and scar formation that can make regeneration at chronic time points more challenging. Herein, we investigated regeneration using a poly(lactide-co-glycolide) multichannel bridge implanted into a chronic SCI following surgical resection of necrotic tissue. We characterized the dynamic injury response and noted that scar formation decreased at 4 and 8 weeks postinjury (wpi), yet macrophage infiltration increased between 4 and 8 wpi. Subsequently, the scar tissue was resected and bridges were implanted at 4 and 8 wpi. We observed robust axon growth into the bridge and remyelination at 6 months after initial injury. Axon densities were increased for 8 week bridge implantation relative to 4 week bridge implantation, whereas greater myelination, particularly by Schwann cells, was observed with 4 week bridge implantation. The process of bridge implantation did not significantly decrease the postinjury function. Collectively, this chronic model follows the pathophysiology of human SCI, and bridge implantation allows for clear demarcation of the regenerated tissue. These data demonstrate that bridge implantation into chronic SCI supports regeneration and provides a platform to investigate strategies to buttress and expand regeneration of neural tissue at chronic time points.

Published

2019

7. Combinatorial lentiviral gene delivery of pro-oligodendrogenic factors for improving myelination of regenerating axons after spinal cord injury.

Author

Smith, Dominique R, Smith, Dominique R, Margul, Daniel J, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Johnson, Mitchell, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Margul, Daniel J, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Johnson, Mitchell, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in paralysis below the injury and strategies are being developed that support axonal regrowth, yet recovery lags, in part, because many axons are not remyelinated. Herein, we investigated strategies to increase myelination of regenerating axons by overexpression of platelet-derived growth factor (PDGF)-AA and noggin either alone or in combination in a mouse SCI model. Noggin and PDGF-AA have been identified as factors that enhance recruitment and differentiation of endogenous progenitors to promote myelination. Lentivirus encoding for these factors was delivered from a multichannel bridge, which we have previously shown creates a permissive environment and supports robust axonal growth through channels. The combination of noggin+PDGF enhanced total myelination of regenerating axons relative to either factor alone, and importantly, enhanced functional recovery relative to the control condition. The increase in myelination was consistent with an increase in oligodendrocyte-derived myelin, which was also associated with a greater density of cells of an oligodendroglial lineage relative to each factor individually and control conditions. These results suggest enhanced myelination of regenerating axons by noggin+PDGF that act on oligodendrocyte-lineage cells post-SCI, which ultimately led to improved functional outcomes.

Published

2019

8. PLG Bridge Implantation in Chronic SCI Promotes Axonal Elongation and Myelination.

Author

Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Munsell, Mary K, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Dumont, Courtney M, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Munsell, Mary K, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) is a devastating condition that may cause permanent functional loss below the level of injury, including paralysis and loss of bladder, bowel, and sexual function. Patients are rarely treated immediately, and this delay is associated with tissue loss and scar formation that can make regeneration at chronic time points more challenging. Herein, we investigated regeneration using a poly(lactide-co-glycolide) multichannel bridge implanted into a chronic SCI following surgical resection of necrotic tissue. We characterized the dynamic injury response and noted that scar formation decreased at 4 and 8 weeks postinjury (wpi), yet macrophage infiltration increased between 4 and 8 wpi. Subsequently, the scar tissue was resected and bridges were implanted at 4 and 8 wpi. We observed robust axon growth into the bridge and remyelination at 6 months after initial injury. Axon densities were increased for 8 week bridge implantation relative to 4 week bridge implantation, whereas greater myelination, particularly by Schwann cells, was observed with 4 week bridge implantation. The process of bridge implantation did not significantly decrease the postinjury function. Collectively, this chronic model follows the pathophysiology of human SCI, and bridge implantation allows for clear demarcation of the regenerated tissue. These data demonstrate that bridge implantation into chronic SCI supports regeneration and provides a platform to investigate strategies to buttress and expand regeneration of neural tissue at chronic time points.

Published

2019

9. Combinatorial lentiviral gene delivery of pro-oligodendrogenic factors for improving myelination of regenerating axons after spinal cord injury.

Author

Smith, Dominique R, Smith, Dominique R, Margul, Daniel J, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Johnson, Mitchell, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Smith, Dominique R, Smith, Dominique R, Margul, Daniel J, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Johnson, Mitchell, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in paralysis below the injury and strategies are being developed that support axonal regrowth, yet recovery lags, in part, because many axons are not remyelinated. Herein, we investigated strategies to increase myelination of regenerating axons by overexpression of platelet-derived growth factor (PDGF)-AA and noggin either alone or in combination in a mouse SCI model. Noggin and PDGF-AA have been identified as factors that enhance recruitment and differentiation of endogenous progenitors to promote myelination. Lentivirus encoding for these factors was delivered from a multichannel bridge, which we have previously shown creates a permissive environment and supports robust axonal growth through channels. The combination of noggin+PDGF enhanced total myelination of regenerating axons relative to either factor alone, and importantly, enhanced functional recovery relative to the control condition. The increase in myelination was consistent with an increase in oligodendrocyte-derived myelin, which was also associated with a greater density of cells of an oligodendroglial lineage relative to each factor individually and control conditions. These results suggest enhanced myelination of regenerating axons by noggin+PDGF that act on oligodendrocyte-lineage cells post-SCI, which ultimately led to improved functional outcomes.

Published

2019

10. Aligned hydrogel tubes guide regeneration following spinal cord injury.

Author

Dumont, Courtney M, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Ciciriello, Andrew J, Strnadova, Katerina, Park, Jonghyuck, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Dumont, Courtney M, Dumont, Courtney M, Carlson, Mitchell A, Munsell, Mary K, Ciciriello, Andrew J, Strnadova, Katerina, Park, Jonghyuck, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Directing the organization of cells into a tissue with defined architectures is one use of biomaterials for regenerative medicine. To this end, hydrogels are widely investigated as they have mechanical properties similar to native soft tissues and can be formed in situ to conform to a defect. Herein, we describe the development of porous hydrogel tubes fabricated through a two-step polymerization process with an intermediate microsphere phase that provides macroscale porosity (66.5%) for cell infiltration. These tubes were investigated in a spinal cord injury model, with the tubes assembled to conform to the injury and to provide an orientation that guides axons through the injury. Implanted tubes had good apposition and were integrated with the host tissue due to cell infiltration, with a transient increase in immune cell infiltration at 1 week that resolved by 2 weeks post injury compared to a gelfoam control. The glial scar was significantly reduced relative to control, which enabled robust axon growth along the inner and outer surface of the tubes. Axon density within the hydrogel tubes (1744 axons/mm2) was significantly increased more than 3-fold compared to the control (456 axons/mm2), with approximately 30% of axons within the tube myelinated. Furthermore, implantation of hydrogel tubes enhanced functional recovery relative to control. This modular assembly of porous tubes to fill a defect and directionally orient tissue growth could be extended beyond spinal cord injury to other tissues, such as vascular or musculoskeletal tissue. STATEMENT OF SIGNIFICANCE: Tissue engineering approaches that mimic the native architecture of healthy tissue are needed following injury. Traditionally, pre-molded scaffolds have been implemented but require a priori knowledge of wound geometries. Conversely, hydrogels can conform to any injury, but do not guide bi-directional regeneration. In this work, we investigate the feasibility of a system of modular hydrogel tubes to promo

Published

2019

11. Intravascular innate immune cells reprogrammed via intravenous nanoparticles to promote functional recovery after spinal cord injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Zhang, Yining, Saito, Eiji, Gurczynski, Steve J, Moore, Bethany B, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Zhang, Yining, Saito, Eiji, Gurczynski, Steve J, Moore, Bethany B, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Traumatic primary spinal cord injury (SCI) results in paralysis below the level of injury and is associated with infiltration of hematogenous innate immune cells into the injured cord. Methylprednisolone has been applied to reduce inflammation following SCI, yet was discontinued due to an unfavorable risk-benefit ratio associated with off-target effects. In this study, i.v. administered poly(lactide-coglycolide) nanoparticles were internalized by circulating monocytes and neutrophils, reprogramming these cells based on their physicochemical properties and not by an active pharmaceutical ingredient, to exhibit altered biodistribution, gene expression, and function. Approximately 80% of nanoparticle-positive immune cells were observed within the injury, and, additionally, the overall accumulation of innate immune cells at the injury was reduced 4-fold, coinciding with down-regulated expression of proinflammatory factors and increased expression of antiinflammatory and proregenerative genes. Furthermore, nanoparticle administration induced macrophage polarization toward proregenerative phenotypes at the injury and markedly reduced both fibrotic and gliotic scarring 3-fold. Moreover, nanoparticle administration with the implanted multichannel bridge led to increased numbers of regenerating axons, increased myelination with about 40% of axons myelinated, and an enhanced locomotor function (score of 6 versus 3 for control group). These data demonstrate that nanoparticles provide a platform that limits acute inflammation and tissue destruction, at a favorable risk-benefit ratio, leading to a proregenerative microenvironment that supports regeneration and functional recovery. These particles may have applications to trauma and potentially other inflammatory diseases.

Published

2019

12. Reducing inflammation through delivery of lentivirus encoding for anti-inflammatory cytokines attenuates neuropathic pain after spinal cord injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Recently, many clinical trials have challenged the efficacy of current therapeutics for neuropathic pain after spinal cord injury (SCI) due to their life-threatening side-effects including addictions. Growing evidence suggests that persistent inflammatory responses after primary SCI lead to an imbalance between anti-inflammation and pro-inflammation, resulting in pathogenesis and maintenance of neuropathic pain. Conversely, a variety of data suggest that inflammation contributes to regeneration. Herein, we investigated long-term local immunomodulation using anti-inflammatory cytokine IL-10 or IL-4-encoding lentivirus delivered from multichannel bridges. Multichannel bridges provide guidance for axonal outgrowth and act as delivery vehicles. Anti-inflammatory cytokines were hypothesized to modulate the pro-nociceptive inflammatory niche and promote axonal regeneration, leading to neuropathic pain attenuation. Gene expression analyses demonstrated that IL-10 and IL-4 decreased pro-nociceptive genes expression versus control. Moreover, these factors resulted in an increased number of pro-regenerative macrophages and restoration of normal nociceptors expression pattern. Furthermore, the combination of bridges with anti-inflammatory cytokines significantly alleviated both mechanical and thermal hypersensitivity relative to control and promoted axonal regeneration. Collectively, these studies highlight that immunomodulatory strategies target multiple barriers to decrease secondary inflammation and attenuate neuropathic pain after SCI.

Published

2018

13. Feasibility study on mouse live imaging after spinal cord injury and poly(lactide-co-glycolide) bridge implantation.

Author

Anzalone, Andrea, Anzalone, Andrea, Chacko, Jenu V, Nishi, Rebecca A, Dumont, Courtney, Smith, Dominique, Shea, Lonnie D, Digman, Michelle A, Cummings, Brian J, Anderson, Aileen J, Anzalone, Andrea, Anzalone, Andrea, Chacko, Jenu V, Nishi, Rebecca A, Dumont, Courtney, Smith, Dominique, Shea, Lonnie D, Digman, Michelle A, Cummings, Brian J, and Anderson, Aileen J

Abstract

Spinal cord injury (SCI) causes permanent paralysis below the damaged area. SCI is linked to neuronal death, demyelination, and limited ability of neuronal fibers to regenerate. Regeneration capacity is limited by the presence of many inhibitory factors in the spinal cord environment. The use of poly(lactide-co-glycolide) (PLG) bridges has demonstrated the ability to sustain long-term regeneration after SCI in a cervical hemisection mouse model. Critically, imaging of regenerating fibers and the myelination status of these neuronal filaments is a severe limitation to progress in SCI research. We used a transgenic mouse model that selectively expresses fluorescent reporters (eGFP) in the neuronal fibers of the spinal cord. We implanted a PLG bridge at C5 vertebra after hemisection and evaluated in live animals' neuronal fibers at the bridge interface and within the bridge 8 weeks postimplant. These in vivo observations were correlated with in situ evaluation 12 weeks postimplantation. We sectioned the spinal cords and performed fluorescent bioimaging on the sections to observe neuronal fibers going through the bridge. In parallel, to visualize myelination of regenerated axons, we exploited the characteristics of the third-harmonic generation arising from the myelin structure in these fixed sections.

Published

2018

14. Spinal Progenitor-Laden Bridges Support Earlier Axon Regeneration Following Spinal Cord Injury.

Author

Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Impact statementSpinal cord injury (SCI) results in loss of tissue innervation below the injury. Spinal progenitors have a greater ability to repair the damage and can be injected into the injury, but their regenerative potential is hampered by their poor survival after transplantation. Biomaterials can create a cell delivery platform and generate a more hospitable microenvironment for the progenitors within the injury. In this work, polymeric bridges are used to deliver embryonic spinal progenitors to the injury, resulting in increased progenitor survival and subsequent regeneration and functional recovery, thus demonstrating the importance of combined therapeutic approaches for SCI.

Published

2018

15. Local Immunomodulation with Anti-inflammatory Cytokine-Encoding Lentivirus Enhances Functional Recovery after Spinal Cord Injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Margul, Daniel J, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Margul, Daniel J, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Trauma to the spinal cord and associated secondary inflammation can lead to permanent loss of sensory and motor function below the injury level, with the resulting environment serving as a barrier that limits regeneration. In this study, we investigate the localized expression of anti-inflammatory cytokines IL-10 and IL-4 via lentiviral transduction in multichannel bridges. Porous multichannel bridges provide physical guidance for axonal outgrowth with the cytokines hypothesized to modulate the neuroinflammatory microenvironment and enhance axonal regeneration. Gene expression analyses indicated that induced IL-10 and IL-4 expression decreased expression of pro-inflammatory genes and increased pro-regenerative genes relative to control. Moreover, these factors led to increased numbers of axons and myelination, with approximately 45% of axons myelinated and the number of oligodendrocyte myelinated axons significantly increased by 3- to 4-fold. Furthermore, the combination of a bridge with IL-10 and IL-4 expression improved locomotor function after injury to an average score of 6 relative to an average score of 3 for injury alone. Collectively, these studies highlight the potential for localized immunomodulation to decrease secondary inflammation and enhance regeneration that may have numerous applications.

Published

2018

16. Spinal Progenitor-Laden Bridges Support Earlier Axon Regeneration Following Spinal Cord Injury.

Author

Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Impact statementSpinal cord injury (SCI) results in loss of tissue innervation below the injury. Spinal progenitors have a greater ability to repair the damage and can be injected into the injury, but their regenerative potential is hampered by their poor survival after transplantation. Biomaterials can create a cell delivery platform and generate a more hospitable microenvironment for the progenitors within the injury. In this work, polymeric bridges are used to deliver embryonic spinal progenitors to the injury, resulting in increased progenitor survival and subsequent regeneration and functional recovery, thus demonstrating the importance of combined therapeutic approaches for SCI.

Published

2018

17. Reducing inflammation through delivery of lentivirus encoding for anti-inflammatory cytokines attenuates neuropathic pain after spinal cord injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Recently, many clinical trials have challenged the efficacy of current therapeutics for neuropathic pain after spinal cord injury (SCI) due to their life-threatening side-effects including addictions. Growing evidence suggests that persistent inflammatory responses after primary SCI lead to an imbalance between anti-inflammation and pro-inflammation, resulting in pathogenesis and maintenance of neuropathic pain. Conversely, a variety of data suggest that inflammation contributes to regeneration. Herein, we investigated long-term local immunomodulation using anti-inflammatory cytokine IL-10 or IL-4-encoding lentivirus delivered from multichannel bridges. Multichannel bridges provide guidance for axonal outgrowth and act as delivery vehicles. Anti-inflammatory cytokines were hypothesized to modulate the pro-nociceptive inflammatory niche and promote axonal regeneration, leading to neuropathic pain attenuation. Gene expression analyses demonstrated that IL-10 and IL-4 decreased pro-nociceptive genes expression versus control. Moreover, these factors resulted in an increased number of pro-regenerative macrophages and restoration of normal nociceptors expression pattern. Furthermore, the combination of bridges with anti-inflammatory cytokines significantly alleviated both mechanical and thermal hypersensitivity relative to control and promoted axonal regeneration. Collectively, these studies highlight that immunomodulatory strategies target multiple barriers to decrease secondary inflammation and attenuate neuropathic pain after SCI.

Published

2018

18. Feasibility study on mouse live imaging after spinal cord injury and poly(lactide-co-glycolide) bridge implantation.

Author

Anzalone, Andrea, Anzalone, Andrea, Chacko, Jenu V, Nishi, Rebecca A, Dumont, Courtney, Smith, Dominique, Shea, Lonnie D, Digman, Michelle A, Cummings, Brian J, Anderson, Aileen J, Anzalone, Andrea, Anzalone, Andrea, Chacko, Jenu V, Nishi, Rebecca A, Dumont, Courtney, Smith, Dominique, Shea, Lonnie D, Digman, Michelle A, Cummings, Brian J, and Anderson, Aileen J

Abstract

Spinal cord injury (SCI) causes permanent paralysis below the damaged area. SCI is linked to neuronal death, demyelination, and limited ability of neuronal fibers to regenerate. Regeneration capacity is limited by the presence of many inhibitory factors in the spinal cord environment. The use of poly(lactide-co-glycolide) (PLG) bridges has demonstrated the ability to sustain long-term regeneration after SCI in a cervical hemisection mouse model. Critically, imaging of regenerating fibers and the myelination status of these neuronal filaments is a severe limitation to progress in SCI research. We used a transgenic mouse model that selectively expresses fluorescent reporters (eGFP) in the neuronal fibers of the spinal cord. We implanted a PLG bridge at C5 vertebra after hemisection and evaluated in live animals' neuronal fibers at the bridge interface and within the bridge 8 weeks postimplant. These in vivo observations were correlated with in situ evaluation 12 weeks postimplantation. We sectioned the spinal cords and performed fluorescent bioimaging on the sections to observe neuronal fibers going through the bridge. In parallel, to visualize myelination of regenerated axons, we exploited the characteristics of the third-harmonic generation arising from the myelin structure in these fixed sections.

Published

2018

19. Spinal Progenitor-Laden Bridges Support Earlier Axon Regeneration Following Spinal Cord Injury.

Author

Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Dumont, Courtney M, Dumont, Courtney M, Munsell, Mary K, Carlson, Mitchell A, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Impact statementSpinal cord injury (SCI) results in loss of tissue innervation below the injury. Spinal progenitors have a greater ability to repair the damage and can be injected into the injury, but their regenerative potential is hampered by their poor survival after transplantation. Biomaterials can create a cell delivery platform and generate a more hospitable microenvironment for the progenitors within the injury. In this work, polymeric bridges are used to deliver embryonic spinal progenitors to the injury, resulting in increased progenitor survival and subsequent regeneration and functional recovery, thus demonstrating the importance of combined therapeutic approaches for SCI.

Published

2018

20. Local Immunomodulation with Anti-inflammatory Cytokine-Encoding Lentivirus Enhances Functional Recovery after Spinal Cord Injury.

Author

Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Margul, Daniel J, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Park, Jonghyuck, Park, Jonghyuck, Decker, Joseph T, Margul, Daniel J, Smith, Dominique R, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Trauma to the spinal cord and associated secondary inflammation can lead to permanent loss of sensory and motor function below the injury level, with the resulting environment serving as a barrier that limits regeneration. In this study, we investigate the localized expression of anti-inflammatory cytokines IL-10 and IL-4 via lentiviral transduction in multichannel bridges. Porous multichannel bridges provide physical guidance for axonal outgrowth with the cytokines hypothesized to modulate the neuroinflammatory microenvironment and enhance axonal regeneration. Gene expression analyses indicated that induced IL-10 and IL-4 expression decreased expression of pro-inflammatory genes and increased pro-regenerative genes relative to control. Moreover, these factors led to increased numbers of axons and myelination, with approximately 45% of axons myelinated and the number of oligodendrocyte myelinated axons significantly increased by 3- to 4-fold. Furthermore, the combination of a bridge with IL-10 and IL-4 expression improved locomotor function after injury to an average score of 6 relative to an average score of 3 for injury alone. Collectively, these studies highlight the potential for localized immunomodulation to decrease secondary inflammation and enhance regeneration that may have numerous applications.

Published

2018

21. Reducing neuroinflammation by delivery of IL-10 encoding lentivirus from multiple-channel bridges.

Author

Margul, Daniel J, Margul, Daniel J, Park, Jonghyuck, Boehler, Ryan M, Smith, Dominique R, Johnson, Mitchell A, McCreedy, Dylan A, He, Ting, Ataliwala, Aishani, Kukushliev, Todor V, Liang, Jesse, Sohrabi, Alireza, Goodman, Ashley G, Walthers, Christopher M, Shea, Lonnie D, Seidlits, Stephanie K, Margul, Daniel J, Margul, Daniel J, Park, Jonghyuck, Boehler, Ryan M, Smith, Dominique R, Johnson, Mitchell A, McCreedy, Dylan A, He, Ting, Ataliwala, Aishani, Kukushliev, Todor V, Liang, Jesse, Sohrabi, Alireza, Goodman, Ashley G, Walthers, Christopher M, Shea, Lonnie D, and Seidlits, Stephanie K

Abstract

The spinal cord is unable to regenerate after injury largely due to growth-inhibition by an inflammatory response to the injury that fails to resolve, resulting in secondary damage and cell death. An approach that prevents inhibition by attenuating the inflammatory response and promoting its resolution through the transition of macrophages to anti-inflammatory phenotypes is essential for the creation of a growth permissive microenvironment. Viral gene delivery to induce the expression of anti-inflammatory factors provides the potential to provide localized delivery to alter the host inflammatory response. Initially, we investigated the effect of the biomaterial and viral components of the delivery system to influence the extent of cell infiltration and the phenotype of these cells. Bridge implantation reduces antigen-presenting cell infiltration at day 7, and lentivirus addition to the bridge induces a transient increase in neutrophils in the spinal cord at day 7 and macrophages at day 14. Delivery of a lentivirus encoding IL-10, an anti-inflammatory factor that inhibits immune cell activation and polarizes the macrophage population towards anti-inflammatory phenotypes, reduced neutrophil infiltration at both day 7 and day 28. Though IL-10 lentivirus did not affect macrophages number, it skewed the macrophage population toward an anti-inflammatory M2 phenotype and altered macrophage morphology. Additionally, IL-10 delivery resulted in improved motor function, suggesting reduced secondary damage and increased sparing. Taken together, these results indicate that localized expression of anti-inflammatory factors, such as IL-10, can modulate the inflammatory response following spinal cord injury, and may be a key component of a combinatorial approach that targets the multiple barriers to regeneration and functional recovery.

Published

2016

22. Dynamic transcription factor activity networks in response to independently altered mechanical and adhesive microenvironmental cues.

Author

Peñalver Bernabé, Beatriz, Peñalver Bernabé, Beatriz, Shin, Seungjin, Rios, Peter D, Broadbelt, Linda J, Shea, Lonnie D, Seidlits, Stephanie K, Peñalver Bernabé, Beatriz, Peñalver Bernabé, Beatriz, Shin, Seungjin, Rios, Peter D, Broadbelt, Linda J, Shea, Lonnie D, and Seidlits, Stephanie K

Abstract

Multiple aspects of the local extracellular environment profoundly affect cell phenotype and function. Physical and chemical cues in the environment trigger intracellular signaling cascades that ultimately activate transcription factors (TFs) - powerful regulators of the cell phenotype. TRACER (TRanscriptional Activity CEll aRrays) was employed for large-scale, dynamic quantification of TF activity in human fibroblasts cultured on hydrogels with a controlled elastic modulus and integrin ligand density. We identified three groups of TFs: responders to alterations in ligand density alone, substrate stiffness or both. Dynamic networks of regulatory TFs were constructed computationally and revealed distinct TF activity levels, directionality (i.e., activation or inhibition), and dynamics for adhesive and mechanical cues. Moreover, TRACER networks predicted conserved hubs of TF activity across multiple cell types, which are significantly altered in clinical fibrotic tissues. Our approach captures the distinct and overlapping effects of adhesive and mechanical stimuli, identifying conserved signaling mechanisms in normal and disease states.

Published

2016

23. Semi-automated counting of axon regeneration in poly(lactide co-glycolide) spinal cord bridges.

Author

McCreedy, Dylan A, McCreedy, Dylan A, Margul, Daniel J, Seidlits, Stephanie K, Antane, Jennifer T, Thomas, Ryan J, Sissman, Gillian M, Boehler, Ryan M, Smith, Dominique R, Goldsmith, Sam W, Kukushliev, Todor V, Lamano, Jonathan B, Vedia, Bansi H, He, Ting, Shea, Lonnie D, McCreedy, Dylan A, McCreedy, Dylan A, Margul, Daniel J, Seidlits, Stephanie K, Antane, Jennifer T, Thomas, Ryan J, Sissman, Gillian M, Boehler, Ryan M, Smith, Dominique R, Goldsmith, Sam W, Kukushliev, Todor V, Lamano, Jonathan B, Vedia, Bansi H, He, Ting, and Shea, Lonnie D

Abstract

BackgroundSpinal cord injury (SCI) is a debilitating event with multiple mechanisms of degeneration leading to life-long paralysis. Biomaterial strategies, including bridges that span the injury and provide a pathway to reconnect severed regions of the spinal cord, can promote partial restoration of motor function following SCI. Axon growth through the bridge is essential to characterizing regeneration, as recovery can occur via other mechanisms such as plasticity. Quantitative analysis of axons by manual counting of histological sections can be slow, which can limit the number of bridge designs evaluated. In this study, we report a semi-automated process to resolve axon numbers in histological sections, which allows for efficient analysis of large data sets.New methodAxon numbers were estimated in SCI cross-sections from animals implanted with poly(lactide co-glycolide) (PLG) bridges with multiple channels for guiding axons. Immunofluorescence images of histological sections were filtered using a Hessian-based approach prior to threshold detection to improve the signal-to-noise ratio and filter out background staining associated with PLG polymer.ResultsSemi-automated counting successfully recapitulated average axon densities and myelination in a blinded PLG bridge implantation study.Comparison with existing methodsAxon counts obtained with the semi-automated technique correlated well with manual axon counts from blinded independent observers across sections with a wide range of total axons.ConclusionsThis semi-automated detection of Hessian-filtered axons provides an accurate and significantly faster alternative to manual counting of axons for quantitative analysis of regeneration following SCI.

Published

2016

24. Dynamic transcription factor activity networks in response to independently altered mechanical and adhesive microenvironmental cues.

Author

Peñalver Bernabé, Beatriz, Peñalver Bernabé, Beatriz, Shin, Seungjin, Rios, Peter D, Broadbelt, Linda J, Shea, Lonnie D, Seidlits, Stephanie K, Peñalver Bernabé, Beatriz, Peñalver Bernabé, Beatriz, Shin, Seungjin, Rios, Peter D, Broadbelt, Linda J, Shea, Lonnie D, and Seidlits, Stephanie K

Abstract

Multiple aspects of the local extracellular environment profoundly affect cell phenotype and function. Physical and chemical cues in the environment trigger intracellular signaling cascades that ultimately activate transcription factors (TFs) - powerful regulators of the cell phenotype. TRACER (TRanscriptional Activity CEll aRrays) was employed for large-scale, dynamic quantification of TF activity in human fibroblasts cultured on hydrogels with a controlled elastic modulus and integrin ligand density. We identified three groups of TFs: responders to alterations in ligand density alone, substrate stiffness or both. Dynamic networks of regulatory TFs were constructed computationally and revealed distinct TF activity levels, directionality (i.e., activation or inhibition), and dynamics for adhesive and mechanical cues. Moreover, TRACER networks predicted conserved hubs of TF activity across multiple cell types, which are significantly altered in clinical fibrotic tissues. Our approach captures the distinct and overlapping effects of adhesive and mechanical stimuli, identifying conserved signaling mechanisms in normal and disease states.

Published

2016

25. Reducing neuroinflammation by delivery of IL-10 encoding lentivirus from multiple-channel bridges.

Author

Margul, Daniel J, Margul, Daniel J, Park, Jonghyuck, Boehler, Ryan M, Smith, Dominique R, Johnson, Mitchell A, McCreedy, Dylan A, He, Ting, Ataliwala, Aishani, Kukushliev, Todor V, Liang, Jesse, Sohrabi, Alireza, Goodman, Ashley G, Walthers, Christopher M, Shea, Lonnie D, Seidlits, Stephanie K, Margul, Daniel J, Margul, Daniel J, Park, Jonghyuck, Boehler, Ryan M, Smith, Dominique R, Johnson, Mitchell A, McCreedy, Dylan A, He, Ting, Ataliwala, Aishani, Kukushliev, Todor V, Liang, Jesse, Sohrabi, Alireza, Goodman, Ashley G, Walthers, Christopher M, Shea, Lonnie D, and Seidlits, Stephanie K

Abstract

The spinal cord is unable to regenerate after injury largely due to growth-inhibition by an inflammatory response to the injury that fails to resolve, resulting in secondary damage and cell death. An approach that prevents inhibition by attenuating the inflammatory response and promoting its resolution through the transition of macrophages to anti-inflammatory phenotypes is essential for the creation of a growth permissive microenvironment. Viral gene delivery to induce the expression of anti-inflammatory factors provides the potential to provide localized delivery to alter the host inflammatory response. Initially, we investigated the effect of the biomaterial and viral components of the delivery system to influence the extent of cell infiltration and the phenotype of these cells. Bridge implantation reduces antigen-presenting cell infiltration at day 7, and lentivirus addition to the bridge induces a transient increase in neutrophils in the spinal cord at day 7 and macrophages at day 14. Delivery of a lentivirus encoding IL-10, an anti-inflammatory factor that inhibits immune cell activation and polarizes the macrophage population towards anti-inflammatory phenotypes, reduced neutrophil infiltration at both day 7 and day 28. Though IL-10 lentivirus did not affect macrophages number, it skewed the macrophage population toward an anti-inflammatory M2 phenotype and altered macrophage morphology. Additionally, IL-10 delivery resulted in improved motor function, suggesting reduced secondary damage and increased sparing. Taken together, these results indicate that localized expression of anti-inflammatory factors, such as IL-10, can modulate the inflammatory response following spinal cord injury, and may be a key component of a combinatorial approach that targets the multiple barriers to regeneration and functional recovery.

Published

2016

26. Semi-automated counting of axon regeneration in poly(lactide co-glycolide) spinal cord bridges.

Author

McCreedy, Dylan A, McCreedy, Dylan A, Margul, Daniel J, Seidlits, Stephanie K, Antane, Jennifer T, Thomas, Ryan J, Sissman, Gillian M, Boehler, Ryan M, Smith, Dominique R, Goldsmith, Sam W, Kukushliev, Todor V, Lamano, Jonathan B, Vedia, Bansi H, He, Ting, Shea, Lonnie D, McCreedy, Dylan A, McCreedy, Dylan A, Margul, Daniel J, Seidlits, Stephanie K, Antane, Jennifer T, Thomas, Ryan J, Sissman, Gillian M, Boehler, Ryan M, Smith, Dominique R, Goldsmith, Sam W, Kukushliev, Todor V, Lamano, Jonathan B, Vedia, Bansi H, He, Ting, and Shea, Lonnie D

Abstract

BackgroundSpinal cord injury (SCI) is a debilitating event with multiple mechanisms of degeneration leading to life-long paralysis. Biomaterial strategies, including bridges that span the injury and provide a pathway to reconnect severed regions of the spinal cord, can promote partial restoration of motor function following SCI. Axon growth through the bridge is essential to characterizing regeneration, as recovery can occur via other mechanisms such as plasticity. Quantitative analysis of axons by manual counting of histological sections can be slow, which can limit the number of bridge designs evaluated. In this study, we report a semi-automated process to resolve axon numbers in histological sections, which allows for efficient analysis of large data sets.New methodAxon numbers were estimated in SCI cross-sections from animals implanted with poly(lactide co-glycolide) (PLG) bridges with multiple channels for guiding axons. Immunofluorescence images of histological sections were filtered using a Hessian-based approach prior to threshold detection to improve the signal-to-noise ratio and filter out background staining associated with PLG polymer.ResultsSemi-automated counting successfully recapitulated average axon densities and myelination in a blinded PLG bridge implantation study.Comparison with existing methodsAxon counts obtained with the semi-automated technique correlated well with manual axon counts from blinded independent observers across sections with a wide range of total axons.ConclusionsThis semi-automated detection of Hessian-filtered axons provides an accurate and significantly faster alternative to manual counting of axons for quantitative analysis of regeneration following SCI.

Published

2016

27. Biomaterial bridges enable regeneration and re-entry of corticospinal tract axons into the caudal spinal cord after SCI: Association with recovery of forelimb function.

Author

Pawar, Kiran, Pawar, Kiran, Cummings, Brian J, Thomas, Aline, Shea, Lonnie D, Levine, Ariel, Pfaff, Sam, Anderson, Aileen J, Pawar, Kiran, Pawar, Kiran, Cummings, Brian J, Thomas, Aline, Shea, Lonnie D, Levine, Ariel, Pfaff, Sam, and Anderson, Aileen J

Abstract

Severed axon tracts fail to exhibit robust or spontaneous regeneration after spinal cord injury (SCI). Regeneration failure reflects a combination of factors, including the growth state of neuronal cell bodies and the regeneration-inhibitory environment of the central nervous system. However, while spared circuitry can be retrained, target reinnervation depends on longitudinally directed regeneration of transected axons. This study describes a biodegradable implant using poly(lactide-co-glycolide) (PLG) bridges as a carrier scaffold to support regeneration after injury. In order to detect regeneration of descending neuronal tracts into the bridge, and beyond into intact caudal parenchyma, we developed a mouse cervical implantation model and employed Crym:GFP transgenic mice. Characterization of Crym:GFP mice revealed that descending tracts, including the corticospinal tract, were labeled by green fluorescent protein (GFP), while ascending sensory neurons and fibers were not. Robust co-localization between GFP and neurofilament-200 (NF-200) as well as GFP and GAP-43 was observed at both the rostral and caudal bridge/tissue interface. No evidence of similar regeneration was observed in mice that received gelfoam at the lesion site as controls. Minimal co-localization between GFP reporter labeling and macrophage markers was observed. Taken together, these data suggest that axons originating from descending fiber tracts regenerated, entered into the PLG bridge at the rostral margin, continued through the bridge site, and exited to re-enter host tissue at the caudal edge of the intact bridge. Finally, regeneration through implanted bridges was associated with a reduction in ipsilateral forelimb errors on a horizontal ladder task.

Published

2015

28. Biomaterial bridges enable regeneration and re-entry of corticospinal tract axons into the caudal spinal cord after SCI: Association with recovery of forelimb function.

Author

Pawar, Kiran, Pawar, Kiran, Cummings, Brian J, Thomas, Aline, Shea, Lonnie D, Levine, Ariel, Pfaff, Sam, Anderson, Aileen J, Pawar, Kiran, Pawar, Kiran, Cummings, Brian J, Thomas, Aline, Shea, Lonnie D, Levine, Ariel, Pfaff, Sam, and Anderson, Aileen J

Abstract

Severed axon tracts fail to exhibit robust or spontaneous regeneration after spinal cord injury (SCI). Regeneration failure reflects a combination of factors, including the growth state of neuronal cell bodies and the regeneration-inhibitory environment of the central nervous system. However, while spared circuitry can be retrained, target reinnervation depends on longitudinally directed regeneration of transected axons. This study describes a biodegradable implant using poly(lactide-co-glycolide) (PLG) bridges as a carrier scaffold to support regeneration after injury. In order to detect regeneration of descending neuronal tracts into the bridge, and beyond into intact caudal parenchyma, we developed a mouse cervical implantation model and employed Crym:GFP transgenic mice. Characterization of Crym:GFP mice revealed that descending tracts, including the corticospinal tract, were labeled by green fluorescent protein (GFP), while ascending sensory neurons and fibers were not. Robust co-localization between GFP and neurofilament-200 (NF-200) as well as GFP and GAP-43 was observed at both the rostral and caudal bridge/tissue interface. No evidence of similar regeneration was observed in mice that received gelfoam at the lesion site as controls. Minimal co-localization between GFP reporter labeling and macrophage markers was observed. Taken together, these data suggest that axons originating from descending fiber tracts regenerated, entered into the PLG bridge at the rostral margin, continued through the bridge site, and exited to re-enter host tissue at the caudal edge of the intact bridge. Finally, regeneration through implanted bridges was associated with a reduction in ipsilateral forelimb errors on a horizontal ladder task.

Published

2015

29. Long-term characterization of axon regeneration and matrix changes using multiple channel bridges for spinal cord regeneration.

Author

Tuinstra, Hannah M, Tuinstra, Hannah M, Margul, Daniel J, Goodman, Ashley G, Boehler, Ryan M, Holland, Samantha J, Zelivyanskaya, Marina L, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Tuinstra, Hannah M, Tuinstra, Hannah M, Margul, Daniel J, Goodman, Ashley G, Boehler, Ryan M, Holland, Samantha J, Zelivyanskaya, Marina L, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in loss of sensory and motor function below the level of injury and has limited available therapies. The host response to SCI is typified by limited endogenous repair, and biomaterial bridges offer the potential to alter the microenvironment to promote regeneration. Porous multiple channel bridges implanted into the injury provide stability to limit secondary damage and support cell infiltration that limits cavity formation. At the same time, the channels provide a path that physically directs axon growth across the injury. Using a rat spinal cord hemisection injury model, we investigated the dynamics of axon growth, myelination, and scar formation within and around the bridge in vivo for 6 months, at which time the bridge has fully degraded. Axons grew into and through the channels, and the density increased overtime, resulting in the greatest axon density at 6 months postimplantation, despite complete degradation of the bridge by that time point. Furthermore, the persistence of these axons contrasts with reports of axonal dieback in other models and is consistent with axon stability resulting from some degree of connectivity. Immunostaining of axons revealed both motor and sensory origins of the axons found in the channels of the bridge. Extensive myelination was observed throughout the bridge at 6 months, with centrally located and peripheral channels seemingly myelinated by oligodendrocytes and Schwann cells, respectively. Chondroitin sulfate proteoglycan deposition was restricted to the edges of the bridge, was greatest at 1 week, and significantly decreased by 6 weeks. The dynamics of collagen I and IV, laminin, and fibronectin deposition varied with time. These studies demonstrate that the bridge structure can support substantial long-term axon growth and myelination with limited scar formation.

Published

2014

30. Sonic hedgehog and neurotrophin-3 increase oligodendrocyte numbers and myelination after spinal cord injury.

Author

Thomas, Aline M, Thomas, Aline M, Seidlits, Stephanie K, Goodman, Ashley G, Kukushliev, Todor V, Hassani, Donna M, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Thomas, Aline M, Thomas, Aline M, Seidlits, Stephanie K, Goodman, Ashley G, Kukushliev, Todor V, Hassani, Donna M, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in loss of sensory and motor function below the level of injury and has limited available therapies. Multiple channel bridges have been investigated as a means to create a permissive environment for regeneration, with channels supporting axonal growth through the injury. Bridges support robust axon growth and myelination. Here, we investigated the cell types that myelinate axons in the bridges and whether over-expression of trophic factors can enhance myelination. Lentivirus encoding for neurotrophin-3 (NT3), sonic hedgehog (SHH) and the combination of these factors was delivered from bridges implanted into a lateral hemisection defect at T9/T10 in mice, and the response of endogenous progenitor cells within the spinal cord was investigated. Relative to control, the localized, sustained expression of these factors significantly increased growth of regenerating axons into the bridge and enhanced axon myelination 8 weeks after injury. SHH decreased the number of Sox2(+) cells and increased the number of Olig2(+) cells, whereas NT3 alone or in combination with SHH enhanced the numbers of GFAP(+) and Olig2(+) cells relative to control. For delivery of lentivirus encoding for either factor, we identified cells at various stages of differentiation along the oligodendrocyte lineage (e.g., O4(+), GalC(+)). Expression of NT3 enhanced myelination primarily by infiltrating Schwann cells, whereas SHH over-expression substantially increased myelination by oligodendrocytes. These studies further establish biomaterial-mediated gene delivery as a promising tool to direct activation and differentiation of endogenous progenitor cells for applications in regenerative medicine.

Published

2014

31. Sonic hedgehog and neurotrophin-3 increase oligodendrocyte numbers and myelination after spinal cord injury.

Author

Thomas, Aline M, Thomas, Aline M, Seidlits, Stephanie K, Goodman, Ashley G, Kukushliev, Todor V, Hassani, Donna M, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Thomas, Aline M, Thomas, Aline M, Seidlits, Stephanie K, Goodman, Ashley G, Kukushliev, Todor V, Hassani, Donna M, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in loss of sensory and motor function below the level of injury and has limited available therapies. Multiple channel bridges have been investigated as a means to create a permissive environment for regeneration, with channels supporting axonal growth through the injury. Bridges support robust axon growth and myelination. Here, we investigated the cell types that myelinate axons in the bridges and whether over-expression of trophic factors can enhance myelination. Lentivirus encoding for neurotrophin-3 (NT3), sonic hedgehog (SHH) and the combination of these factors was delivered from bridges implanted into a lateral hemisection defect at T9/T10 in mice, and the response of endogenous progenitor cells within the spinal cord was investigated. Relative to control, the localized, sustained expression of these factors significantly increased growth of regenerating axons into the bridge and enhanced axon myelination 8 weeks after injury. SHH decreased the number of Sox2(+) cells and increased the number of Olig2(+) cells, whereas NT3 alone or in combination with SHH enhanced the numbers of GFAP(+) and Olig2(+) cells relative to control. For delivery of lentivirus encoding for either factor, we identified cells at various stages of differentiation along the oligodendrocyte lineage (e.g., O4(+), GalC(+)). Expression of NT3 enhanced myelination primarily by infiltrating Schwann cells, whereas SHH over-expression substantially increased myelination by oligodendrocytes. These studies further establish biomaterial-mediated gene delivery as a promising tool to direct activation and differentiation of endogenous progenitor cells for applications in regenerative medicine.

Published

2014

32. Long-term characterization of axon regeneration and matrix changes using multiple channel bridges for spinal cord regeneration.

Author

Tuinstra, Hannah M, Tuinstra, Hannah M, Margul, Daniel J, Goodman, Ashley G, Boehler, Ryan M, Holland, Samantha J, Zelivyanskaya, Marina L, Cummings, Brian J, Anderson, Aileen J, Shea, Lonnie D, Tuinstra, Hannah M, Tuinstra, Hannah M, Margul, Daniel J, Goodman, Ashley G, Boehler, Ryan M, Holland, Samantha J, Zelivyanskaya, Marina L, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Abstract

Spinal cord injury (SCI) results in loss of sensory and motor function below the level of injury and has limited available therapies. The host response to SCI is typified by limited endogenous repair, and biomaterial bridges offer the potential to alter the microenvironment to promote regeneration. Porous multiple channel bridges implanted into the injury provide stability to limit secondary damage and support cell infiltration that limits cavity formation. At the same time, the channels provide a path that physically directs axon growth across the injury. Using a rat spinal cord hemisection injury model, we investigated the dynamics of axon growth, myelination, and scar formation within and around the bridge in vivo for 6 months, at which time the bridge has fully degraded. Axons grew into and through the channels, and the density increased overtime, resulting in the greatest axon density at 6 months postimplantation, despite complete degradation of the bridge by that time point. Furthermore, the persistence of these axons contrasts with reports of axonal dieback in other models and is consistent with axon stability resulting from some degree of connectivity. Immunostaining of axons revealed both motor and sensory origins of the axons found in the channels of the bridge. Extensive myelination was observed throughout the bridge at 6 months, with centrally located and peripheral channels seemingly myelinated by oligodendrocytes and Schwann cells, respectively. Chondroitin sulfate proteoglycan deposition was restricted to the edges of the bridge, was greatest at 1 week, and significantly decreased by 6 weeks. The dynamics of collagen I and IV, laminin, and fibronectin deposition varied with time. These studies demonstrate that the bridge structure can support substantial long-term axon growth and myelination with limited scar formation.

Published

2014

33. Identification of a PARP Inhibitor Sensitivity Signature in Breast Cancer Using a Novel Transcription Factor Activity Array

Author

NORTHWESTERN UNIV EVANSTON IL, Shea, Lonnie D, NORTHWESTERN UNIV EVANSTON IL, and Shea, Lonnie D

Abstract

A system for the large scale, dynamic quantification of transcription factor activity was applied to investigate the mechanism of action for PARP inhibitors. Of the 34 TFs investigated, 15 had differential activity in the presence of the PARP inhibitor olaparib. A few of the TF had differential activity in BRCA1-wild type and BRCA1-null cells. This differential activity may underlie why some patients respond whereas others are resistant. In addition, five PARP-1 inhibitor resistant clones were established from BRCA1-null type cells. Cell array analysis from these clones will provide us valuable insights into addressing the occurrence of resistance. We are continuing to investigate these factors to identify whether targeting these additional pathways can increase the efficacy or reduce resistance to PARP inhibitors., The original document contains color images.

Published

2012

34. Vascular endothelial growth factor and fibroblast growth factor 2 delivery from spinal cord bridges to enhance angiogenesis following injury.

Author

UCL - SSS/LDRI - Louvain Drug Research Institute, De Laporte, Laura, des Rieux, Anne, Tuinstra, Hannah M, Zelivyanskaya, Marina L, De Clerck, Nora M, Postnov, Andrei A, Préat, Véronique, Shea, Lonnie D, UCL - SSS/LDRI - Louvain Drug Research Institute, De Laporte, Laura, des Rieux, Anne, Tuinstra, Hannah M, Zelivyanskaya, Marina L, De Clerck, Nora M, Postnov, Andrei A, Préat, Véronique, and Shea, Lonnie D

Abstract

The host response to spinal cord injury can lead to an ischemic environment that can induce cell death and limits cell transplantation approaches to promote spinal cord regeneration. Spinal cord bridges that provide a localized and sustained release of vascular endothelial growth factor (VEGF) and fibroblast growth factor 2 (FGF-2) were investigated for their ability to promote angiogenesis and nerve growth within the injury. Bridges were fabricated by fusion of poly(lactide-co-glycolide) microspheres using a gas foaming/particulate leaching technique, and proteins were incorporated by encapsulation into the microspheres and/or mixing with the microspheres before foaming. Compared to the mixing method, encapsulation reduced the losses during leaching and had a slower protein release, while VEGF was released more rapidly than FGF-2. In vivo implantation of bridges loaded with VEGF enhanced the levels of VEGF within the injury at 1 week, and bridges releasing VEGF and FGF-2 increased the infiltration of endothelial cells and the formation of blood vessel at 6 weeks postimplantation. Additionally, substantial neurofilament staining was observed within the bridge; however, no significant difference was observed between bridges with or without protein. Bridges releasing angiogenic factors may provide an approach to overcome an ischemic environment that limits regeneration and cell transplantation-based approaches. © 2011 Wiley Periodicals, Inc. J Biomed Mater Res Part A, 2011.

Published

2011

35. Fibrin hydrogels for non-viral vector delivery in vitro

Author

UCL - MD/FARM - Ecole de pharmacie, des Rieux, Anne, Shikanov, Ariella, Shea, Lonnie D., UCL - MD/FARM - Ecole de pharmacie, des Rieux, Anne, Shikanov, Ariella, and Shea, Lonnie D.

Abstract

Fibrin based hydrogels have been employed in vitro as a scaffold to promote tissue formation and investigate underlying molecular mechanisms. These hydrogels support a variety of cellular processes, and are being developed to enhance the presentation of biological cues, or to tailor the biological cues for specific tissues. The presentation of these cues could alternatively be enhanced through gene delivery, which can be employed to induce the expression of tissue inductive factors in the local environment. This report investigates gene delivery within fibrin hydrogels for two in vitro models of tissue growth: i) cell encapsulation within and ii) cell seeding onto the hydrogel. Naked plasmid and lipoplexes can be efficiently entrapped within the hydrogel, and after 1 day in solution more than 70% of the entrapped DNA is retained within the gel, with a sustained release observed for at least 19 days. Encapsulated lipoplexes did not aggregate and retained their original size. Transgene expression in vitro by delivery of lipoplexes was a function of the fibrinogen and DNA concentration. For encapsulated cells, all cells had intracellular plasmid and transgene expression persisted for at least 10 days, with maximal levels achieved at day 1. For cell infiltration, expression levels were less than those observed for encapsulation, and expression increased throughout the culture period. The increasing expression levels suggest that lipoplexes retain their activity after encapsulation; however, interactions between fibrin and the lipoplexes likely limit internalization. The inclusion of non-viral vectors into fibrin-based hydrogels can be employed to induce transgene expression of encapsulated and infiltrating cells, and may be employed with in vitro models of tissue growth to augment the intrinsic bioactivity of fibrin.

Published

2009

36. Layered PLG scaffolds for in vivo plasmid delivery.

Author

UCL - MD/FARM - Ecole de pharmacie, Rives, Christopher B, des Rieux, Anne, Zelivyanskaya, Marina, Stock, Stuart R, Lowe, William L, Shea, Lonnie D, UCL - MD/FARM - Ecole de pharmacie, Rives, Christopher B, des Rieux, Anne, Zelivyanskaya, Marina, Stock, Stuart R, Lowe, William L, and Shea, Lonnie D

Abstract

Gene delivery from tissue engineering scaffolds can induce localized expression of tissue inductive factors to direct the function of progenitor cells, either endogenous or transplanted. In this report, we developed a layering approach for fabricating scaffolds with encapsulated plasmid, and investigated in vivo gene transfer following implantation into intraperitoneal fat, a widely used site for cell transplantation. Porous poly(lactide-co-glycolide) (PLG) scaffolds were fabricated using a gas foaming method, in which a non-porous layer containing plasmid was inserted between two porous polymer layers. The layered scaffold design decouples the scaffold structural requirements from its function as a drug delivery vehicle, and significantly increased the plasmid incorporation efficiency relative to scaffolds formed without layers. For multiple plasmid doses (200, 400, and 800mug), transgene expression levels peaked during the first few days and then declined over a period of 1-2 weeks. Transfected cells were observed both in the surrounding adipose tissue and within the scaffold interior. Macrophages were identified as an abundantly transfected cell type. Scaffolds delivering plasmid encoding fibroblast growth factor-2 (FGF-2) stimulated a 40% increase in the total vascular volume fraction relative to controls at 2 weeks. Scaffold-based gene delivery systems capable of localized transgene expression provide a platform for inductive and cell transplantation approaches in regenerative medicine.

Published

2009

37. Engineered Bone Development from a Pre-Osteoblast Cell Line on Three-Dimensional Scaffolds

Author

Shea, Lonnie D., Wang, Dian, Franceschi, Renny T., Mooney, David J., Shea, Lonnie D., Wang, Dian, Franceschi, Renny T., and Mooney, David J.

Abstract

Bone regeneration is based on the hypothesis that healthy progenitor cells, either recruited or delivered to an injured site, can ultimately regenerate lost or damaged tissue. Three-dimensional porous polymer scaffolds may enhance bone regeneration by creating and maintaining a space that facilitates progenitor cell migration, proliferation, and differentiation. As an initial step to test this possibility, osteogenic cells were cultured on scaffolds fabricated from biodegradable polymers, and bone development on these scaffolds was evaluated. Porous polymer scaffolds were fabricated from biodegradable polymers of lactide and glycolide. MC3T3-E1 cells were statically seeded onto the polymer scaffolds and cultured in vitro in the presence of ascorbic acid and β-glycerol phosphate. The cells proliferated during the first 4 weeks in culture and formed a space-filling tissue. Collagen messenger RNA levels remained high in these cells throughout the time in culture, which is consistent with an observed increase in collagen deposition on the polymer scaffold. Mineralization of the deposited collagen was initially observed at 4 weeks and subsequently increased. The onset of mineralization corresponded to increased mRNA levels for two osteoblast-specific genes: osteocalcin and bone sialoprotein. Culture of cell/polymer constructs for 12 weeks led to formation of a three-dimensional tissue with architecture similar to that of native bone. These studies demonstrate that osteoblasts within a three-dimensional engineered tissue follow the classic differentiation pathway described for two-dimensional culture. Polymer scaffolds such as these may ultimately be used clinically to enhance bone regeneration by delivering or recruiting progenitor cells to the wound site.

Published

2009