Computationally efficient beam elements for accurate stresses in sandwich laminates and laminated composites with delaminations.

Laminated composites are prone to delamination failure due to the lack of reinforcement through the thickness. Therefore, during the design process the initiation and propagation of delaminations should be accounted for as early as possible. This paper presents computationally efficient nine degree-of-freedom (dof) and eight-dof shear locking-free beam elements using the mixed form of the refined zigzag theory (RZT(m)). The corresponding nine-dof and eight-dof elements use the anisoparametric and constrained anisoparametric interpolation schemes, respectively, to eliminate shear locking in slender beams. The advantage of the present element over previous RZT beam elements is that no post-processing is required to accurately model the transverse shear stress while maintaining the computational efficiency of a low-order beam element. Comparisons with high-fidelity finite element models and three-dimensional elasticity solutions show that the elements can robustly and accurately predict the displacement field, axial stress and transverse shear stress through the thickness of a sandwich beam or a composite laminate with an embedded delamination. In fact, the accuracy and computational efficiency of predicting stresses in laminates with embedded delaminations make the present elements attractive choices for RZT-based delamination initiation and propagation methodologies available in the literature.

Spinal shock revisited: a four-phase model.

Spinal shock has been of interest to clinicians for over two centuries. Advances in our understanding of both the neurophysiology of the spinal cord and neuroplasticity following spinal cord injury have provided us with additional insight into the phenomena of spinal shock. In this review, we provide a historical background followed by a description of a novel four-phase model for understanding and describing spinal shock. Clinical implications of the model are discussed as well.

Delayed grafting of BDNF and NT-3 producing fibroblasts into the injured spinal cord stimulates sprouting, partially rescues axotomized red nucleus neurons from loss and atrophy, and provides limited regeneration.

Ex vivo gene therapy, utilizing modified fibroblasts that deliver BDNF or NT-3 to the acutely injured spinal cord, has been shown to elicit regeneration and recovery of function in the adult rat. Delayed grafting into the injured spinal cord is of great clinical interest as a model for treatment of chronic injury but may pose additional obstacles that are not present after acute injury, such as the need to remove an established scar, increased retrograde cell loss and/or atrophy, and diminished capacity for regeneration by neurons which may be doubly injured. The purpose of the present study was to determine if delayed grafting of neurotrophin secreting fibroblasts would have anatomical effects similar to those seen in acute grafting models. We grafted a mixture of BDNF and NT-3 producing fibroblasts or control fibroblasts into a complete unilateral cervical hemisection after a 6-week delay. Fourteen weeks after delayed grafting we found that both the neurotrophin secreting fibroblasts and control fibroblasts survived, but that only the neurotrophin secreting grafts provided a permissive environment for host axon growth, as indicated by immunostaining for RT-97, a marker for axonal neurofilaments, GAP-43, a marker for elongating axons, CGRP, a marker for dorsal root axons, and 5-HT, a marker for raphe spinal axons, within the graft. Anterograde tracing of the uninjured vestibulospinal tract showed growth into neurotrophin producing transplants but not into control grafts, while anterograde tracing of the axotomized rubrospinal tract showed a small number of regenerating axons within the genetically modified grafts, but none in control grafts. The neurotrophin expressing grafts, but not the control grafts, significantly reduced retrograde degeneration and atrophy in the injured red nucleus. Grafts of BDNF + NT-3 expressing fibroblasts delayed 6 weeks after injury therefore elicit growth from intact segmental and descending spinal tracts, stimulate modest regenerative growth by rubrospinal axons, and partially rescue axotomized supraspinal neurons and protect them from atrophy. The regeneration of rubrospinal axons into delayed transplants was much less than has been observed when similar transplants were placed acutely into a lateral funiculus or, after a 4-week delay, into a hemisection lesion. This suggests that the regenerative capacity of chronically injured red nucleus neurons was markedly diminished. The increased GAP43 reactivity in the corticospinal tracts ipsilaterally and contralaterally to the combination grafts suggests that these axons remain responsive to the neurotrophins, that the neurotrophins may stimulate both regenerative and sprouting responses, and that the grafted cells continue to secrete the neurotrophins.

Transplantation of genetically modified cells contributes to repair and recovery from spinal injury.

The effects of transplantation of fibroblasts genetically modified to produce brain derived neurotrophin factor (Fb/BDNF) on rescue of axotomized neurons, axonal growth and recovery of function was tested in a lateral funiculus lesion model in adult rats. Operated control animals included those in which the lesion was filled with gelfoam implant (Hx) and those in which the cavity was filled with unmodified fibroblasts (Fb). Both Fb/BDNF and Fb transplants survived and filled the lesion site. Unoperated control groups showed a marked retrograde death of Red nucleus neurons contralateral to the lesion; Fb/BDNF recipients showed a significant rescue effect. Anterograde and retrograde labeling studies indicated no regeneration of rubrospinal axons into the lesion/transplant in operated control animals, but regeneration into, around, and through the transplant into the host was seen in the Fb/BDNF recipients. All animals showed deficits on the more challenging behavioral tests but the Fb/BDNF recipients showed fewer deficits, particularly in tests of spontaneous vertical exploration, horizontal rope crossing and a sensory test (patch removal). The improved function on these tests in the Fb/BDNF recipients was abolished by a second lateral funiculus lesion rostral to the transport site. These results indicate that delivery of neurotrophic factors by grafting genetically modified cells can improve repair and function after spinal injury.

Transplants of cells genetically modified to express neurotrophin-3 rescue axotomized Clarke's nucleus neurons after spinal cord hemisection in adult rats.

To test the idea that genetically engineered cells can rescue axotomized neurons, we transplanted fibroblasts and immortalized neural stem cells (NSCs) modified to express neurotrophic factors into the injured spinal cord. The neurotrophin-3 (NT-3) or nerve growth factor (NGF) transgene was introduced into these cells using recombinant retroviral vectors containing an internal ribosome entry site (IRES) sequence and the beta-galactosidase or alkaline phosphatase reporter gene. Bioassay confirmed biological activity of the secreted neurotrophic factors. Clarke's nucleus (CN) axons, which project to the rostral spinal cord and cerebellum, were cut unilaterally in adult rats by T8 hemisection. Rats received transplants of fibroblasts or NSCs genetically modified to express NT-3 or NGF and a reporter gene, only a reporter gene, or no transplant. Two months postoperatively, grafted cells survived at the hemisection site. Grafted fibroblasts and NSCs expressed a reporter gene and immunoreactivity for the NGF or NT-3 transgene. Rats receiving no transplant or a transplant expressing only a reporter gene showed a 30% loss of CN neurons in the L1 segment on the lesioned side. NGF-expressing transplants produced partial rescue compared with hemisection alone. There was no significant neuron loss in rats receiving grafts of either fibroblasts or NSCs engineered to express NT-3. We postulate that NT-3 mediates survival of CN neurons through interaction with trkC receptors, which are expressed on CN neurons. These results support the idea that NT-3 contributes to long-term survival of axotomized CN neurons and show that genetically modified cells rescue axotomized neurons as efficiently as fetal CNS transplants.

Grafting of encapsulated BDNF-producing fibroblasts into the injured spinal cord without immune suppression in adult rats.

Grafting of genetically modified cells that express therapeutic products is a promising strategy in spinal cord repair. We have previously grafted BDNF-producing fibroblasts (FB/BDNF) into injured spinal cord of adult rats, but survival of these cells requires a strict protocol of immune suppression with cyclosporin A (CsA). To develop a transplantation strategy without the detrimental effects of CsA, we studied the properties of FB/BDNF that were encapsulated in alginate-poly-L-ornithine, which possesses a semipermeable membrane that allows production and diffusion of a therapeutic product while protecting the cells from the host immune system. Our results show that encapsulated FB/BDNF, placed in culture, can survive, secrete bioactive BDNF and continue to grow for at least one month. Furthermore, encapsulated cells that have been stored in liquid nitrogen retain the ability to grow and express the transgene. Encapsulated FB/BDNF survive for at least one month after grafting into an adult rat cervical spinal cord injury site in the absence of immune suppression. Transgene expression decreased within two weeks after grafting but resumed when the cells were harvested and re-cultured, suggesting that soluble factors originating from the host immune response may contribute to the downregulation. In the presence of capsules that contained FB/BDNF, but not cell-free control capsules, there were many axons and dendrites at the grafting site. We conclude that alginate encapsulation of genetically modified cells may be an effective strategy for delivery of therapeutic products to the injured spinal cord and may provide a permissive environment for host axon growth in the absence of immune suppression.

Intraspinal implants of fibrin glue containing glial cell line-derived neurotrophic factor promote dorsal root regeneration into spinal cord.

OBJECTIVE: The purpose of this study was to determine whether glial cell line-derived neurotrophic factor (GDNF) delivered intraspinally via a fibrin glue (FG) enhanced regeneration of cut dorsal root (DR). METHODS: FG containing GDNF was inserted into aspiration cavities in the lumbar enlargement of adult rats. The transected L5 DR stump was placed at the bottom of the cavity and sandwiched between the FG and the spinal cord. Regenerated DR axons were labeled with horseradish peroxidase (HRP) or with immunohistochemical methods for calcitonin gene-related peptide (CGRP). RESULTS: Primary afferent axons labeled with HRP regenerated into the spinal cord, received GDNF, and made frequent arborization there. Some of these were myelinated axons that established synapses on intraspinal neuronal profiles. CGRP-immunoreactive DR axons extended into the motor neurons and formed prominent varicosities around their cell bodies. Only a few axons regenerated into the spinal cords given FG without GDNF. CONCLUSIONS: Our results indicate that GDNF enhances regeneration of DR into the adult rat spinal cord and that GDNF may be effectively supplied to the intraspinal injury site via FG. Because the regenerated axons establish synapses on intraspinal neurons, this therapeutic strategy has the potential to help to rebuild spinal reflex circuits interrupted by spinal cord injury.

Transplantation of genetically modified fibroblasts expressing BDNF in adult rats with a subtotal hemisection improves specific motor and sensory functions.

OBJECTIVE: We have previously reported that grafting fibroblasts genetically modified to express brain-derived neurotrophic factor (BDNF) into a subtotal cervical hemisection site that destroys the entire lateral funiculus will promote regeneration of rubrospinal axons and growth of other axons, prevent atrophy and death of axotomized red nucleus neurons, and improve forelimb use during spontaneous vertical exploration. We have now extended these studies by using additional sensorimotor tests to examine recovery. METHODS: The range of tests used included those in which the intervention did not improve recovery, those in which the intervention was associated with recovery, and those that showed little deficit. The selected tasks tested both sensory and motor functions and both forelimb and forelimb function. We used the open-field locomotor rating scale (BBB), locomotion on a narrow beam, forelimb use during swimming, horizontal rope walking, and a somatosensory asymmetry (patch-removal) test. After testing during an 8-week recovery period, a second lesion was made just rostral to the initial lesion/transplant site to test the role of the transplant in recovery. The rats were then retested for a further 5 weeks after the repeated lesion. RESULTS: The horizontal rope, swim, and patch-removal tests were reliably sensitive to the subtotal hemisection injury. Fb/BDNF-transplanted animals recovered motor functions on the horizontal rope-crossing test, and this recovery was abolished by a second lesion just rostral to the first lesion/transplant. In the patch-removal test, the latency to contact the affected limb was shorter in Fb/BDNF-treated rats than in the control group, and this effect was completely abolished by a second lesion. CONCLUSIONS: The rope-crossing and patch-removal tests are particularly useful tasks for assessing the beneficial effects of BDNF-expressing grafts in this injury model.

Characterization and intraspinal grafting of EGF/bFGF-dependent neurospheres derived from embryonic rat spinal cord.

Recent advances in the isolation and characterization of neural precursor cells suggest that they have properties that would make them useful transplants for the treatment of central nervous system disorders. We demonstrate here that spinal cord cells isolated from embryonic day 14 Sprague-Dawley and Fischer 344 rats possess characteristics of precursor cells. They proliferate as undifferentiated neurospheres in the presence of EGF and bFGF and can be maintained in vitro or frozen, expanded and induced to differentiate into both neurons and glia. Exposure of these cells to serum in the absence of EGF and bFGF promotes differentiation into astrocytes; treatment with retinoic acid promotes differentiation into neurons. Spinal cord cells labeled with a nuclear dye or a recombinant adenovirus vector carrying the lacZ gene survive grafting into the injured spinal cord of immunosuppressed Sprague-Dawley rats and non-immunosuppressed Fischer 344 rats for up to 4 months following transplantation. In the presence of exogenously supplied BDNF, the grafted cells differentiate into both neurons and glia. These spinal cord cell grafts are permissive for growth by several populations of host axons, especially when combined with exogenous BDNF administration, as demonstrated by penetration into the graft of axons immunopositive for 5-HT and CGRP. Thus, precursor cells isolated from the embryonic spinal cord of rats, expanded in culture and genetically modified, are a promising type of transplant for repair of the injured spinal cord.

Fibroblasts genetically modified to produce BDNF support regrowth of chronically injured serotonergic axons.

Cells genetically modified to release a variety of growth and/or neurotrophic factors have been used for transplantation into the injured spinal cord as a means to deliver therapeutic products. Axon growth into and through such transplants has been demonstrated after intervention after an acute injury. The present study examined their potential to support regeneration in a chronic injury condition. Five weeks after a cervical hemisection in adult rats, the lesion site was debrided of scar tissue and expanded in both rostral and caudal directions. Animals received a transplant of cultured normal fibroblasts (control) or fibroblasts genetically modified to produce brain-derived neurotrophic factor (BDNF). Six weeks later, animals were killed to determine the extent of growth of serotonergic axons into the transplant. Axons immunoreactive for serotonin (5-HT-ir) were found to cross the rostral interface of host spinal cord readily with either type of fibroblast cell transplant, but the number and density of 5-HT-ir axons extending into the BDNF-producing transplants was markedly greater than those in the control fibroblasts. Axons coursed in all directions among normal fibroblast transplants, whereas growth was more oriented along a longitudinal plane when BDNF was being released by the transplanted cells. The length of growth and the percentage of the transplant length occupied by 5-HT-ir axons were significantly greater in BDNF-producing transplants than in the normal fibroblasts. Many serotonergic axons approached the caudal end of the BDNF-producing cell transplants, although most failed to penetrate the host spinal cord distal to the lesion. These results indicate that whereas fibroblast cell transplants alone can support regrowth of axons from chronically injured supraspinal neurons, modification of these cells to produce BDNF results in a significant increase in the extent of growth into the transplant.

Single injections of a DNA plasmid that contains the human Bcl-2 gene prevent loss and atrophy of distinct neuronal populations after spinal cord injury in adult rats.

Spinal cord injury in adult mammals causes atrophy or loss of axotomized neurons. We have previously found that the product of the antiapoptotic gene Bcl-2, delivered by intraspinal injection of a DNA plasmid, reduces atrophy and loss of axotomized Clarke's nucleus neurons in adult rats. Here we studied whether the same treatment protects axotomized red nucleus (RN) neurons. Two months after the right dorsolateral funiculus was ablated in adult Sprague-Dawley rats by C3/C4 subtotal hemisection, there was approximately 48% loss of RN neurons in the magnocellular portion of the RN contralateral to the lesion and atrophy of many surviving neurons. When a DNA plasmid encoding the human Bcl-2 gene and the bacterial reporter gene LacZ, complexed with cationic lipids, was injected just rostral to the subtotal hemisection site, 87% of RN neurons survived, and there was partial, but robust, protection from atrophy. These and our previous results indicated that intraspinal administration of the Bcl-2 gene can prevent retrograde cell loss and reduce atrophy of axotomized RN and Clarke's nucleus neurons in adult rats and provide an effective means to rescue neurons whose survival depends on different growth factors.

Red nucleus neurons of Bcl-2 over-expressing mice are protected from cell death induced by axotomy.

The Bcl-2 proto-oncogene regulates apoptosis and prevents cell death. We studied the effect of Bcl-2 gene over-expression on the survival of axotomized red nucleus (RN) neurons after unilateral hemisection at cervical segment 4/5 (C4/5) in mice. Seventy-five percent of RN neurons survived in Bcl-2 over-expressing mice 1 or 2 months after surgery compared with only 55% of RN neurons in wild-type mice. However, Bcl-2 gene over-expression does not prevent lesion-induced shrinkage of RN neurons.

Embryonic central nervous system transplants mediate adult dorsal root regeneration into host spinal cord.

OBJECTIVE: The aim of this study was to determine whether embryonic central nervous system transplants assisted cut dorsal root axons of adult rats to regenerate into the spinal cord. METHODS: Rats received transplants of embryonic spinal cord, hippocampus, or neocortex into dorsal quadrant cavities aspirated in the lumbar enlargement. The transected L5 dorsal root stump was secured between the transplant and the spinal cord. Regenerated dorsal roots were subsequently labeled by using immunohistochemical methods to detect calcitonin gene-related peptide. RESULTS: Calcitonin gene-related peptide-immunoreactive axons extended into all host spinal cords examined, but the patterns of regrowth differed in rats that had received embryonic spinal cord and brain transplants. In rats with embryonic spinal cord transplants, regenerated axons traversed the dorsal root/spinal cord interface, entered the spinal cord, and frequently formed plexuses with arborizations in motoneuron pools; some of these axons established synapses on spinal cord neurons. In rats with embryonic brain transplants, regenerated axons were diffusely distributed in the spinal cord but did not form plexuses. Few axons regenerated into the spinal cords of lesion-only animals. The results of quantitative analyses confirmed these findings. CONCLUSION: These findings suggest that transplants of embryonic spinal cord and brain supply cues that enable cut dorsal roots to regenerate into the host spinal cord and that the cues provided by spinal cord transplants favor more extensive growth than do those provided by brain transplants. These cues are likely to depend in part on neurotrophic effects of embryonic central nervous system tissues. Therefore, embryonic central nervous system transplants, especially spinal cord grafts, may contribute to techniques for restoring interrupted spinal reflex arcs.

Intraspinal delivery of neurotrophin-3 using neural stem cells genetically modified by recombinant retrovirus.

Neural stem cells have been shown to participate in the repair of experimental CNS disorders. To examine their potential in spinal cord repair, we used retroviral vectors to genetically modify a clone of neural stem cells, C17, to overproduce neurotrophin-3 (NT-3). The cells were infected with a retrovirus construct containing the NT-3.IRES.lacZ/neo sequence and cloned by limiting dilution and selection for lacZ expression. We studied the characteristics of the modified neural stem cells in vitro and after transplantation into the intact spinal cord of immunosuppressed adult rats. Our results show that: (i) most of the genetically modified cells express both NT-3 and lacZ genes with a high coexpression ratio in vitro and after transplantation; and (ii) large numbers of the xenografted cells survive in the spinal cord of adult rats for at least 2 months, differentiate into neuronal and glial phenotypes, and migrate for long distances. We conclude that genetically modified neural stem cells, acting as a source of neurotrophic factors, have the potential to participate in spinal cord repair.

Direct agonists for serotonin receptors enhance locomotor function in rats that received neural transplants after neonatal spinal transection.

We analyzed whether acute treatment with serotonergic agonists would improve motor function in rats with transected spinal cords (spinal rats) and in rats that received transplants of fetal spinal cord into the transection site (transplant rats). Neonates received midthoracic spinal transections within 48 hr of birth; transplant rats received fetal (embryonic day 14) spinal cord grafts at the time of transection. At 3 weeks, rats began 1-2 months of training in treadmill locomotion. Rats in the transplant group developed better weight-supported stepping than spinal rats. Systemic administration of two directly acting agonists for serotonergic 5-HT(2) receptor subtypes, quipazine and (+/-)-1-[2, 5]-dimethoxy-4-iodophenyl-2-aminopropane), further increased weight-supported stepping in transplant rats. The improvement was dose-dependent and greatest in rats with poor to moderate baseline weight support. In contrast, indirectly acting serotonergic agonists, which block reuptake of 5-HT (sertraline) or release 5-HT and block its reuptake (D-fenfluramine), failed to enhance motor function. Neither direct nor indirect agonists significantly improved locomotion in spinal rats as a group, despite equivalent upregulation of 5-HT(2) receptors in the lumbar ventral horn of lesioned rats with and without transplants. The distribution of immunoreactive serotonergic fibers within and caudal to the transplant did not appear to correspond to restoration of motor function. Our results confirm our previous demonstration that transplants improve motor performance in spinal rats. Additional stimulation with agonists at subtypes of 5-HT receptors produces a beneficial interaction with transplants that further improves motor competence.

Transplants of fibroblasts genetically modified to express BDNF promote regeneration of adult rat rubrospinal axons and recovery of forelimb function.

Adult mammalian CNS neurons do not normally regenerate their severed axons. This failure has been attributed to scar tissue and inhibitory molecules at the injury site that block the regenerating axons, a lack of trophic support for the axotomized neurons, and intrinsic neuronal changes that follow axotomy, including cell atrophy and death. We studied whether transplants of fibroblasts genetically engineered to produce brain-derived neurotrophic factor (BDNF) would promote rubrospinal tract (RST) regeneration in adult rats. Primary fibroblasts were modified by retroviral-mediated transfer of a DNA construct encoding the human BDNF gene, an internal ribosomal entry site, and a fusion gene of lacZ and neomycin resistance genes. The modified fibroblasts produce biologically active BDNF in vitro. These cells were grafted into a partial cervical hemisection cavity that completely interrupted one RST. One and two months after lesion and transplantation, RST regeneration was demonstrated with retrograde and anterograde tracing techniques. Retrograde tracing with fluorogold showed that approximately 7% of RST neurons regenerated axons at least three to four segments caudal to the transplants. Anterograde tracing with biotinylated dextran amine revealed that the RST axons regenerated through and around the transplants, grew for long distances within white matter caudal to the transplant, and terminated in spinal cord gray matter regions that are the normal targets of RST axons. Transplants of unmodified primary fibroblasts or Gelfoam alone did not elicit regeneration. Behavioral tests demonstrated that recipients of BDNF-producing fibroblasts showed significant recovery of forelimb usage, which was abolished by a second lesion that transected the regenerated axons.

Neurotrophic agents in fibrin glue mediate adult dorsal root regeneration into spinal cord.

OBJECTIVE: The aim of the present study was to determine whether neurotrophic factors (NTFs) exogenously administered in fibrin glue assisted cut dorsal root axons of adult rats to regenerate into the spinal cord. METHODS: Rats received intraspinal implants of fibrin glue containing neurotrophin-3, brain-derived NTF, ciliary NTF, or Dulbecco's modified Eagle's medium (control) into left dorsal quadrant cavities aspirated in the lumbar enlargement. The transected L5 dorsal root stump was placed at the bottom of the lesion cavity and was secured between the fibrin glue and the spinal cord. Regenerated dorsal root axons were subsequently labeled with immunohistochemical methods to demonstrate those that contained calcitonin gene-related peptide. RESULTS: Calcitonin gene-related peptide-immunoreactive dorsal root axons regenerated across the dorsal root-spinal cord interface of rats with fibrin glue containing neurotrophin-3, brain-derived NTF, or ciliary NTF, entered the spinal cord, and frequently arborized within clusters of motoneuronal cell bodies. Only a few axons regenerated into the spinal cord of animals with fibrin glue implants that lacked NTF, and their growth within the spinal cord was extremely limited. The results of quantitative studies confirmed these observations. CONCLUSION: Our results indicate that neurotrophin-3, brain-derived NTF, and ciliary NTF enhance dorsal root regeneration into spinal cord and that fibrin glue is an effective medium for intraspinal delivery of NTF. This method of delivering NTF may therefore provide a strategy for restoring injured spinal reflex arcs.

DNA plasmid that codes for human Bcl-2 gene preserves axotomized Clarke's nucleus neurons and reduces atrophy after spinal cord hemisection in adult rats.

Spinal cord injury in adult mammals causes atrophy or death of some axotomized neurons. The product of the antiapoptotic gene Bcl-2 prevents neuron death in vivo. We delivered Bcl-2 by intraspinal injection of a DNA plasmid encoding this gene to determine if axotomized neurons destined to undergo retrograde death could be rescued. Axons of the right side Clarke's Nucleus (CN) were cut unilaterally in adult Sprague-Dawley rats by T8 hemisection, leaving the contralateral (left) CN as an intact control. Two months postoperatively, there was approximately 35% loss of total CN neurons in the right L1 segment. Only 15% of large CN neurons (>400 microm2), whose axons project to the cerebellum, survived--indicating atrophy and/or death of 85% of these cells. We injected a DNA plasmid encoding the human Bcl-2 gene and the bacterial reporter gene LacZ, which was complexed with cationic lipids, into the right side of segment T8 of the normal spinal cord, or just caudal to the hemisection site. The reporter gene was expressed in the perikarya of right CN neurons at L1 for up to 7 days, but not 14 days. Two months following T8 hemisection and Bcl-2/LacZ DNA injection, there was no significant loss of CN neurons ipsilateral to the lesion. Surprisingly, 61% of large neurons survived, indicating partial protection from atrophy. In contrast, a DNA plasmid that codes for the LacZ reporter gene, but not Bcl-2, did not prevent CN neuron death or atrophy. Administration of the Bcl-2 gene in adult rats and its expression in these CNS neurons prevents retrograde cell death, and also minimizes atrophy. These results may serve as the basis for developing novel gene therapy strategies for patients with spinal cord injury.