Subarachnoid transplant of a human neuronal cell line attenuates chronic allodynia and hyperalgesia after excitotoxic spinal cord injury in the rat.

UNLABELLED: The relief of neuropathic pain after spinal cord injury (SCI) remains daunting, because pharmacologic intervention works incompletely and is accompanied by multiple side effects. Transplantation of human cells that make specific biologic agents that can potentially modulate the sensory responses that are painful would be very useful to treat problems such as pain. To address this need for clinically useful human cells, the human neuronal NT2 cell line was used as a source to isolate a unique human neuronal cell line that synthesizes and secretes/releases the inhibitory neurotransmitters gamma-aminobutyric acid (GABA) and glycine. This new cell line, hNT2.17, expresses an exclusively neuronal phenotype, does not incorporate bromodeoxyuridine during differentiation, and does not express the tumor-related proteins fibroblast growth factor 4 and transforming growth factor-alpha during differentiation after 2 weeks of treatment with retinoic acid and mitotic inhibitors. The transplant of predifferentiated hNT2.17 cells was used in the excitotoxic SCI pain model, after intraspinal injection of the mixed AMPA/metabotropic receptor agonist quisqualic acid (QUIS). When hNT2.17 cells were transplanted into the lumbar subarachnoid space, tactile allodynia and thermal hyperalgesia induced by the injury were quickly and potently reversed. Control cell transplants of nonviable hNT2.17 cells had no effect on the hypersensitivity induced by QUIS. The effects of hNT2.17 cell grafts appeared 1 week after transplants and did not diminish during the 8-week course of the experiment when grafts were placed 2 weeks after SCI. Immunohistochemistry and quantification of the human grafts were used to ensure that many grafted cells were still present and synthesizing GABA at the end of the study. These data suggest that the human neuronal hNT2.17 cells can be used as a "biologic minipump" for antinociception in models of SCI and neuropathic pain. PERSPECTIVE: This study describes the initial characterization and use of a human-derived cell line to treat neuropathic pain that would be suitable for clinical application, once further tested for safety and approved by the Food and Drug Administration. A dose of these human cells could be delivered with a spinal tap and affect the intrathecal spinal environment for sensory system modulation.

Improved neural progenitor cell survival when cografted with chromaffin cells in the rat striatum.

Transplantation of stem and neural progenitor cells hold great promise in the repair of neuronal tissue lost due to injury or disease. However, survival following transplantation to the adult CNS has been poor, likely due to a lack of neurotrophic factors, such as basic fibroblast growth factor (FGF-2), that are used to maintain and expand these cells in culture. Chromaffin cells produce several neurotrophic agents, including FGF-2, which may aid in both neuroprotection following injury and progenitor cell proliferation and survival. In addition, increased CNS catecholamines have been shown to improve functional recovery following insult. Thus, cotransplants of neural progenitor cells and chromaffin cells may be a useful clinical strategy. To address this, the survival of rat cortical progenitors transplanted to the adult rat striatum with and without bovine chromaffin cell cografts was assessed. Progenitors obtained from E14 embryos were prelabeled with bromodeoxyuridine (BrdU) before transplantation to enable later identification. Transplants were made both unilaterally and bilaterally, where animals received a monograft (progenitor cells alone) on one side and a cograft (progenitors + chromaffin cells) on the other. Histological results after 7, 17, and 30 days posttransplant revealed greatly improved survival of BrdU-labeled cells in the cografts and also less infiltration of presumptive immune cells. In addition, perivascular cuffing was seen in the monografts. In vitro progenitor cohorts stained positive for nestin, GFAP, and beta-tubulin III, but in vivo very few cells were found that were double labeled with BrdU and one of these markers. Thus, in contrast to in vitro findings, chromaffin cells did not enhance differentiation of progenitors in vivo during the 30 days posttransplantation. The results of these studies suggest that chromaffin cells may provide neurotrophic support to enhance survival, but not differentiation, of cortical progenitor grafts in the adult CNS.

Direct cell-cell contact required for neurotrophic effect of chromaffin cells on neural progenitor cells.

Previous studies showed that neural progenitor cultures could be maintained without exogenously added FGF-2 when co-cultured with chromaffin cells. In addition, progenitor cells displayed dramatically increased neuronal differentiation in the presence of chromaffin cells. These findings suggested an approach to improved neural progenitor transplant outcomes using co-transplantation or administration of chromaffin cell-derived factors. The aim of this study was to determine whether the observed survival and differentiation effects were due to diffusible factors or required direct cell-cell contact (DC). Rat neural progenitors were cultured under six different conditions: (1) Standard N2 media with FGF-2; (2) N2 without FGF-2; (3) N2 with FGF+conditioned media (CM) from chromaffin cultures; (4) N2 without FGF-2+CM; (5) Transwells (TW), progenitor+chromaffin cells grown together but separated by a membrane allowing movement of diffusible agents but preventing direct contact; (6) direct contact co-cultures of progenitors and chromaffin cells. Cultures were evaluated for survival, proliferation, and differentiation. Cultures with FGF-2 proliferated and formed floating neurospheres while those grown in N2 without FGF-2 failed to thrive. Those grown either with CM or in transwells showed significantly improved survival. Survival was comparable to the exogenous FGF groups when progenitors were allowed direct contact with chromaffin cells. Proliferation was low in all cultures except those receiving exogenous FGF-2. Direct contact co-cultures exhibited a marked increase in beta-tubulin III+ processes compared to all other groups, indicating differentiation towards a neuronal phenotype. The results of this study suggest that diffusible agents produced by chromaffin cells can sustain viable progenitor cells in vitro even in the absence of added FGF-2 but that the effects on progenitor cell neuronal differentiation require direct cell-cell contact.

Analgesic effects of adrenal chromaffin allografts: contingent on special procedures or due to experimenter bias?

Many articles have reported that adrenal chromaffin cell transplants produce analgesic effects. Surprisingly, studies conducted in our laboratory failed to detect analgesic effects of adrenal chromaffin cell transplants. Although we have attempted to replicate the procedures reported to produce analgesic effects with adrenal chromaffin transplants, many of the different cell preparation procedures we have examined are fairly complex, and it is possible that our transplants were not sufficiently viable because of some subtle difference in our cell preparation procedures. In the present study we attempted to replicate as precisely as possible, and with very large groups to maximize statistical power, the simplest and most straightforward procedures previously reported to produce analgesic effects, adrenal allografts in the formalin test. The first experiment, conducted in our laboratories, failed to detect analgesic effects of intrathecal adrenal allografts in the formalin test. Another study conducted at a different research facility confirmed the absence of analgesic effects in the formalin test but verified that analgesic effects of morphine were detectable under the same blinded conditions. In addition, graft viability was verified histologically, but there was no correlation in either experiment between adrenal chromaffin cell number and pain behaviors. These results demonstrate more clearly than any of our previous reports that the analgesic effects of intrathecal adrenal transplants are not reliable and should not be accepted as valid until they can be produced reliably under rigorously blinded conditions.

Enhanced viability and neuronal differentiation of neural progenitors by chromaffin cell co-culture.

The transplantation of neural stem cells and progenitors has potential in restoring lost cellular populations following central nervous system (CNS) injury or disease, but survival and neuronal differentiation in the adult CNS may be insufficient in the absence of exogenous trophic support. Adrenal medullary chromaffin cells produce a trophic cocktail including basic fibroblast growth factor (FGF-2) and neurotrophins. The aim of this study was to evaluate whether chromaffin cells can provide a supportive microenvironment for neural progenitor cells. In order to assess this, the growth and differentiation of neural progenitor cell cultures from embryonic rat cortex were compared in standard FGF-2-supplemented neural progenitor growth media, in standard media but lacking FGF-2, or in media lacking FGF-2 but co-cultured with bovine chromaffin cells. Using bromodeoxyuridine (BrdU)-prelabeling, findings indicated poor survival of progenitor cultures in the absence of FGF-2. In contrast, the addition of chromaffin cells in co-culture appeared to 'rescue' the progenitor cultures and resulted in robust neurospheres containing numerous BrdU-labeled cells interspersed with and closely apposed to chromaffin cells. As indicated by H3 labeling, cells in co-cultures continued to proliferate, but at a substantially reduced rate compared with standard FGF-2 supplemented growth media. The co-cultures contained more beta-tubulin III-positive processes than parallel cultures maintained in FGF-2-supplemented media and these cells displayed a more mature phenotype with numerous varicosities and complex processes. These findings indicate that chromaffin cells can provide a supportive environment for the survival and neuronal differentiation of neural progenitor cells and suggest that their addition may be useful as a sustained source of trophic support to improve outcomes of neural stem cell transplantation.

No detectable analgesic effects in the formalin test even with one million bovine adrenal chromaffin cells.

The present experiments were conducted to identify analgesic agents for transfection into immortalized adrenal chromaffin cell lines to maximize their analgesic potential. Analgesic agents known to be produced by adrenal chromaffin cells were infused intrathecally at a low dose (0.2 microg) which might conceivably be attained by adrenal chromaffin cell transplants. Numerous agents, administered individually and in two-factor combinations, produced significant analgesic effects in the formalin test. Before assessing the potential additive or synergistic effects of these analgesic agents with adrenal chromaffin cells, studies were conducted to demonstrate analgesic effects with adrenal chromaffin cells alone. Analgesic effects were previously reported in the literature with 80-100k intrathecal bovine adrenal chromaffin (BAC) cells; but in the present study 500k purified BAC cells failed to produce detectable analgesic effects. One million purified BAC cells also failed to produce analgesic effects in the formalin test. In a final study, even nicotine-stimulated release from one million purified BAC cells failed to produce analgesic effects in the formalin test. The fact that even one million nicotine-stimulated BAC cells failed to demonstrate therapeutic potential in these blinded experiments under conditions which were clearly sensitive to the analgesic agents produced by BAC cells, raises serious questions about the clinical utility of this experimental treatment.

Adrenal medullary transplants reduce formalin-evoked c-fos expression in the rat spinal cord.

Previous studies have indicated that adrenal medullary chromaffin cells transplanted into the spinal subarachnoid space can alleviate pain behaviors in several animal models. The goal of this study was to assess whether decreased activation of spinal dorsal horn neurons responsive to nociceptive stimuli may contribute to these antinociceptive effects. In order to address this, expression of neural activity marker c-fos in response to intraplantar formalin was evaluated in animals with intrathecal adrenal medullary or control striated muscle transplants. Adrenal medullary transplants significantly attenuated formalin-induced flinching behaviors in both acute and tonic phases of the formalin response, in comparison with control transplanted animals. Fos-like-immunoreactive (Fos-LI) cell numbers were markedly reduced in the dorsal horns of animals with adrenal medullary transplants in comparison to robust Fos-LI expression in control transplanted animals. This reduction was observed in both superficial and deep laminae of the dorsal horn, but the magnitude of the decrease was greatest in lamina V. Similar to reports using other antinociceptive treatments, some residual c-fos expression was observed, particularly in laminae I-II, in animals with adrenal medullary transplants. The results of these studies suggest that adrenal medullary transplants produce antinociception in part by inhibiting spinal dorsal horn neuronal activation in response to noxious stimuli.

TrkC overexpression enhances survival and migration of neural stem cell transplants in the rat spinal cord.

Although CNS axons have the capacity to regenerate after spinal cord injury when provided with a permissive substrate, the lack of appropriate synaptic target sites for regenerating fibers may limit restoration of spinal circuitry. Studies in our laboratory are focused on utilizing neural stem cells to provide new synaptic target sites for regenerating spinal axons following injury. As an initial step, rat neural precursor cells genetically engineered to overexpress the tyrosine kinase C (trkC) neurotrophin receptor were transplanted into the intact rat spinal cord to evaluate their survival and differentiation. Cells were either pretreated in vitro prior to transplantation with trkC ligand neurotrophin-3 (NT-3) to initiate differentiation or exposed to NT-3 in vivo following transplantation via gelfoam or Oxycel. Both treatments enhanced survival of trkC-overexpressing stem cells to nearly 100%, in comparison with approximately 30-50% when either NT-3 or trkC was omitted. In addition, increased migration of trkC-overexpressing cells throughout the spinal gray matter was noted, particularly following in vivo NT-3 exposure. The combined trkC expression and NT-3 treatment appeared to reduce astrocytic differentiation of transplanted neural precursors. Decreased cavitation and increased beta-tubulin fibers were noted in the vicinity of transplanted cells, although the majority of transplanted cells appeared to remain in an undifferentiated state. These findings suggest that genetically engineered neural stem cells in combination with neurotrophin treatment may be a useful addition to strategies for repair of spinal neurocircuitry following injury.

TRANSPLANTATION OF POLYMER ENCAPSULATED PC12 CELLS: USE OF CHITOSAN AS AN IMMOBILIZATION MATRIX.

Polymer capsules were fabricated to encapsulate PC12 cells within a semipermeable and immunoprotective barrier. The inclusion of precipitated chitosan as an immobilization matrix within the polymer capsules increased the survival and physiological functioning of the PC12 cells. In an initial study, HPLC analysis revealed that the inclusion of a chitosan matrix resulted in an increased output of catecholamines from the encapsulated PC12 cells under both basal conditions, and following high potassium depolarization at 2 and 4 wk following encapsulation in vitro. Furthermore, implantation of cohort PC12 cell-loaded capsules into guinea pig striata revealed that chitosan enhanced PC 12 cell survival after 6 wk. A second study determined that 12 wk after implantation into guinea pig striatum, abundant tyrosine hydroxylase-positive PC12 cells were evenly distributed within capsules containing chitosan. The long-term biocompatibility of these implants was good as determined by the absence of inflammatory or immune cells, and minimal GFAP reactivity surrounding the implant site. In contrast, implantation of unencapsulated PC12 cells resulted in a marked host tissue reaction, and destruction of the implanted cells within 4 wk. It is concluded that the inclusion of precipitated chitosan as an immobilization matrix enhanced the viability of encapsulated PC12 cells, and that altering the internal milieu of polymeric capsules may represent an effective transplant strategy for ameliorating human diseases characterized by secretory cell dysfunction.