Transplantation Of Adrenal Chromaffin Cells Research Articles

Phenotypic characteristics of hybrid cells produced by cell fusion of porcine adrenal chromaffin cells with human mesenchymal stem cells: a preliminary study

Background and purpose: Transplantation of adrenal chromaffin cells (CCs) that release endogenous opioid peptides and catecholamines produces significant antinociceptive effects in patients with terminal cancer pain. In clinical practice, however, obtaining a sufficient number of chromaffin cells may not be possible because of the limited availability of human adrenal tissue. Recent works have shown that fusion of bone marrow-derived cells with differentiated cells can occur spontaneously in vivo and acquire the phenotype of the recipient cells. In this study, we investigated the possibility of producing chromaffin-like cells by fusing human bone marrow-derived mesenchymal stem cells (MeSCs) with post-mitotic porcine CCs in vitro with the application of polyethylene glycol (PEG).Methods and results: Before cell-to-cell fusion was initiated, MeSCs and CCs were labeled by fluorescence dyes DiO (green) and Dil (red), respectively. The hybrid cells generated by PEG-mediated fusion expressed a DiO and Dil double-staining with estimated fusion efficiency at ∼40% of the total cell population. Further immunocytochemical examination for tyrosine hydroxylase and methionine enkephalin (markers for CCs) demonstrated positive immuno-reactivity in these hybrid cells 2 weeks post-fusion. More interestingly, some of the hybrid cells showed bromodeoxyuridine (BrdU)-positive immunostaining in the nuclei.Discussion: Our results show that these hybrid cells fused by CCs and MeSCs express some characteristics of the CC phenotype. A subpopulation of these hybrid cells are dividing cells with positive BrdU immunostaining, suggesting that a novel cellular production could be developed by a "reprogramming" mechanism through the application of targeted cell fusion strategies.

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

Abstract: 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. [copy ] 2003 by the American Pain Society

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 μg) 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.

Effects of adrenal medullary transplants on pain-related behaviors following excitotoxic spinal cord injury

Previous studies have shown that intraspinal injection of quisqualic acid (QUIS) produces excitotoxic injury with pathological characteristics similar to those associated with ischemic and traumatic spinal cord injury (SCI). Significant changes in the functional properties of sensory neurons adjacent to the site of injury have also been observed in this model. Additionally, following QUIS injections, mechanical and cold allodynia, combined with excessive grooming behavior have been shown to be the behavioral correlates of these pathological and physiological changes. These behaviors are believed to be related to the clinical conditions of spontaneous and evoked pain following SCI. Given the therapeutic properties of adrenal chromaffin cell transplantation in conditions of neuropathic and cancer pain, it is proposed that the neuroactive substances released from chromaffin cells can alter or prevent the onset and progression of QUIS-induced behavioral changes. The effects of adrenal transplants were evaluated in 14 male Long–Evans rats that received intraspinal injections of QUIS. Pain behaviors, including the progression of excessive grooming behavior ( n=8) and hypersensitivity to mechanical and thermal stimuli ( n=6) were evaluated following transplantation. A 53% increase in mechanical thresholds was observed following adrenal transplants along with a 70% reduction in the area of skin targeted for excessive grooming. These behaviors were not affected in 11 animals receiving transplants of skeletal muscle. The effects of adrenal transplants on cold allodynia consisted of a stabilization of response latencies in contrast to the continued decrease in latencies, i.e., increased sensitivity, following transplants of skeletal muscle. The results are consistent with previous studies showing the therapeutic efficacy of adrenal chromaffin cell transplants in neuropathic pain, and support the use of this treatment strategy for the alleviation of chronic pain following spinal cord injury.

Intrastriatal Transplantation of Rat Adrenal Chromaffin Cells Seeded on Microcarrier Beads Promote Long-Term Functional Recovery in Hemiparkinsonian Rats

Possible biologic treatments for Parkinson's disease, a disorder caused by the deterioration of dopaminergic neurons bridging the nigrostriatal system, have recently focused on fetal cell transplantation. Because of ethical and tissue availability issues concerning fetal cell transplantation, alternative cell sources are being developed. The adrenal medulla has been used as a cell transplant source because of the capacity of the cells to provide catecholamines and to transform into a neuronal phenotype. However, adrenal tissue transplants have shown limited success, primarily because of their lack of long-term viability. Recently, seeding adrenal chromaffin cells on microcarrier beads has been shown to enhance the cell viability following neural transplantation. In the present study, we further investigated whether transplantation of rat adrenal chromaffin cells seeded on microcarrier beads into the striatum of 6-hydroxydopamine-induced hemiparkinsonian rats would result in a sustained functional recovery. Behavioral tests using the apomorphine-induced rotational and elevated body swing tests up to 12 months posttransplantation revealed a significant behavioral recovery in animals that received adrenal chromaffin cells seeded on microcarrier beads compared to animals that received adrenal chromaffin cells alone, medium alone, or beads alone. Histological examination of tissue at 14 months posttransplantation revealed evidence of tyrosine hydroxylase-positive cells and an on-going glial response in animals transplanted with adrenal chromaffin cells seeded on microcarrier beads, in contrast to absence of such immunoreactive responses in the other groups. These findings support a facilitator role for microcarrier beads in transplantation of adrenal chromaffin cells or other cells that are easily rejected by the CNS.

Intraventricular encapsulated calf adrenal chromaffin cells: viable for at least 500 days in vivo without detectable adverse effects on behavioral/cognitive function or host immune sensitization in rats

Numerous studies have reported that adrenal chromaffin cell transplants, including encapsulated xenogeneic adrenal chromaffin cells, have analgesic effects. However, in addition to efficacy, the clinical utility of encapsulated xenogeneic adrenal chromaffin cells for treatment of chronic pain is dependent on the duration of cell viability in vivo, and their relative safety. The objectives of the present study in rats were to: (1) examine encapsulated calf adrenal chromaffin (CAC) cells for evidence of viable cells and continued release of analgesic agents after an extended period in vivo; (2) determine if intraventricular encapsulated CAC cells produce detectable adverse effects on behavioral/cognitive function; and (3) test for evidence of host immune sensitization after an extended period of exposure to encapsulated xenogeneic adrenal chromaffin cells. Results of the present study suggest that some encapsulated CAC cells remain viable for nearly 1.5 years in vivo and continue to produce catecholamines and met-enkephalin. Post-explant device norepinephrine output was equivalent to amounts previously shown to produce analgesic effects with intrathecal implants. Encapsulated adrenal chromaffin cells also appeared relatively safe, even when implanted in the cerebral ventricals, with a lower side-effect profile than systemic morphine (4 mg/kg). There was no evidence that encapsulated CAC-cells implanted in the ventricles affected body weight, spontaneous activity levels, or performance in the delayed matching to position operant task which is sensitive to deficits in learning, memory, attention, motivation, and motor function. Finally, encapsulated CAC cells produced no detectable evidence of host immune sensitization after 16.7 months in vivo, although unencapsulated CAC cells produced a robust immune response even in aged rats. The results of the present study suggest that adrenal chromaffin cells remain viable in vivo for long periods of time, and that long-term exposure to encapsulated xenogeneic adrenal chromaffin cell implants appears relatively safe.

Neurosurgical horizons in Parkinson's disease

Based on recent neuroanatomic and physiologic discoveries, neurosurgical therapies may increasingly complement and extend pharmacologic management of Parkinson's disease. Procedures showing promise include subthalamotomy and pallidotomy; thalamic electrical stimulation may also offer application for tremor control. Transplantation of adrenal chromaffin cells has not been associated with consistent long-term improvement in most patients, and fetal mesencephalic transplantation remains controversial. Trophic factors that may be pivotal to cellular repair and survival of transplanted tissue have potential therapeutic roles when purified and perfused centrally or when the cells that produce the factors are transplanted.

The use of genetically altered astrocytes to provide nerve growth factor to adrenal chromaffin cells grafted into the striatum

Transplantation of adrenal chromaffin cells into the striatum of Parkinson's disease patients is unlikely to become a reliable therapy unless techniques are devised to improve cell survival. To address this issue, we investigated the use of genetically altered astrocytes that constitutively secrete β-nerve growth factor (NGF) to provide trophic support for adrenal chromaffin cells grafted into the dopamine-denervated striatum of the rat. Primary rat astrocytes were altered genetically in vitro by infection with a retroviral vector harboring a mouse β-NGF transgene under constitutive long terminal repeat transcriptional control. Confluent cultures of these genetically altered astrocytes secrete NGF into their culture medium at a rate of approximately 9 pg/10 5 cells/h. This rate of NGF secretion is at least 10-fold higher than that of confluent sister cultures of uninfected astrocytes. The effects of the NGF-secreting astrocytes on the survival and neuronal transformation of dissociated adrenal chromaffin cells were assessed in vitro and following transplantation into the dopamine-denervated striatum of the adult rat. In vitro experiments demonstrated that neuritic outgrowth is stimulated when postnatal day 12 chromaffin cells are grown on a monolayer of the genetically altered astrocytes. When co-grafted with genetically altered astrocytes, young postnatal chromaffin cells displayed extensive neuritic outgrowth within the host brain 2 weeks postimplantation, whereas chromaffin cells grafted alone or with normal astrocytes retain an endocrine-like morphology. Survival of the chromaffin cells is also enhanced 3–6-fold when co-grafted with the genetically altered astrocytes. In addition, the neuronally transformed chromaffin cells appear to lose adrenergic properties as assessed by diminished immunoreactivity to the adrenergic marker, phenylethanolamine-N-methyltransferase. Although their survival is also enhanced approximately 4-fold relative to controls, adult chromaffin cells do not convert to a neuronal morphology when co-grafted with the genetically altered astrocytes. These studies demonstrate that rat astrocytes carrying a mouse NGF transgene provide trophic support for intrastriatal chromaffin cell grafts.