Polymer-encapsulated PC12 Cells Research Articles

Cellular Transplants, 20 Years Later: The Pharma Initiative

Cellular Transplants, 20 Years Later: The Pharma Initiative

Polymer-encapsulated PC-12 cells demonstrate high-affinity uptake of dopamine in vitro and 18F-DOPA uptake and metabolism after intracerebral implantation in nonhuman primates

Intracranial implantation of polymer-encapsulated PC-12 cells has been shown to improve motor behavioral performance in animal models of Parkinson's disease. The purpose of this blinded study was to examine whether such improvement is associated with the active uptake and metabolism of dopamine precursors by intracerebrally implanted polymer-encapsulated PC-12 cells. In an in vitro experiment we demonstrate that 3H-dopamine uptake by PC-12 cells was 10 8 fmol/min x 10 6 cells, and that this uptake can be specifically blocked 88% by the addition of 10 nM of nomifensine. In the in vivo experiments, polymer-encapsulated PC-12 cells were implanted in four MPTP-treated monkeys into the left deep parietal white matter (R1) or left striatum (R2–4). A fifth MPTP-treated monkey (R5) served as a control and received left striatal implants of empty capsules. 18F-Dopa Positron Emission Tomography (PET) imaging was performed on each monkey before and after implantation surgery by blinded investigators. PET images obtained 5–13 wk after implantation demonstrated well delineated focal areas of high 18F-dopa uptake in R1, R2, and R4. The focal area of high 18F-Dopa uptake in R1 precisely coregistered on a brain magnetic resonance image to the site of implantation. R3 (in whom the polymer-encapsulated PC-12 cells demonstrated poor cell survival upon explantation) and R5 (empty capsules) failed to demonstrate any area of increased 18F-dopa uptake in their PET images. Histological examination of the host brain revealed no sprouting of dopaminergic nerve terminals around the implantation sites of the polymer-encapsulated PC-12 cells. These results indicate that the previously noted behavioral improvement after intrastriatal implantation of polymer encapsulated PC-12 cells is at least in part due to their highly specific uptake and metabolism of dopamine precursors. Furthermore, these data suggest that polymer-encapsulated PC-12 cells can store, reuptake, and functionally replenish dopamine and therefore, may be an effective treatment for Parkinson's disease.

Polymer-encapsulated PC-12 cells demonstrate high-affinity uptake of dopamine in vitro and 18F-Dopa uptake and metabolism after intracerebral implantation in nonhuman primates.

Intracranial implantation of polymer-encapsulated PC-12 cells has been shown to improve motor behavioral performance in animal models of Parkinson's disease. The purpose of this blinded study was to examine whether such improvement is associated with the active uptake and metabolism of dopamine precursors by intracerebrally implanted polymer-encapsulated PC-12 cells. In an in vitro experiment we demonstrate that 3H-dopamine uptake by PC-12 cells was 10(8) fmol/min x 10(6) cells, and that this uptake can be specifically blocked 88% by the addition of 10nM of nomifensine. In the in vivo experiments, polymer-encapsulated PC-12 cells were implanted in four MPTP-treated monkeys into the left deep parietal white matter (R1) or left striatum (R2-4). A fifth MPTP-treated monkey (R5) served as a control and received left striatal implants of empty capsules. 18-F-Dopa Positron Emission Tomography (PET) imaging was performed on each monkey before and after implantation surgery by blinded investigators. PET images obtained 5-13 wk after implantation demonstrated well delineated focal areas of high 18F-dopa uptake in R1, R2, and R4. The focal area of high 18F-dopa uptake in R1 precisely coregistered on a brain magnetic resonance image to the site of implantation. R3 (in whom the polymer-encapsulated PC-12 cells demonstrated poor cell survival upon explantation) and R5 (empty capsules) failed to demonstrate any area of increased 18F-dopa uptake in their PET images. Histological examination of the host brain revealed no sprouting of dopaminergic nerve terminals around the implantation sites of the polymer-encapsulated PC-12 cells. These results indicate that the previously noted behavioral improvement after intrastriatal implantation of polymer encapsulated PC-12 cells is at least in part due to their highly specific uptake and metabolism of dopamine precursors. Furthermore, these data suggest that polymer-encapsulated PC-12 cells can store, reuptake, and functionally replenish dopamine and therefore, may be an effective treatment for Parkinson's disease.

Continued presence of intrastriatal but not intraventricular polymer-encapsulated PC12 cells is required for alleviation of behavioral deficits in Parkinsonian rodents

To date, few studies have systematically evaluated the most appropriate location for grafting catecholaminergic cells as a potential treatment for Parkinson's disease (PD). The following study was conducted to determine 1) if placement of catecholamine-secreting encapsulated PC12 cells into the lateral ventricle of 6-OHDAtreated rats is as effective as intrastriatal implants on reducing apomorphine-induced rotational behavior, and 2) to determine if the survival of encapsulated PC12 cells is differentially affected by the implant site. Polymer-encapsulated PC12 cells were implanted into either the striatum or lateral ventricle of unilateral 6-OHDA-lesioned rats. Animals were tested for apomorphine-induced rotations over a 6-wk period. Only those animals that received intrastriatal implants of encapsulated PC12 cells showed a reduction in rotation behavior. Moreover, removal of the devices from the striatum resulted in a return to preimplant rotation levels. Postexplant neurochemical analyses demonstrated that the potassium-evoked L-dopa device output increased in vivo while the potassium-evoked dopamine output from the devices decreased over time in vivo. The location of the implant significantly affected catecholamine output from the PC12 cell-loaded devices. The increase in potassium-evoked L-dopa output was greatest, as was the decrease in potassium-evoked dopamine output, from those devices implanted in the striatum. Basal output of dopamine and DOPAC was also significantly higher from devices explanted from the lateral ventricle. These results demonstrate that the continued presence of intrastriatal implants of encapsulated PC12 cells is required to maintain the behavioral effects in 6-OHDA-lesioned rats. In addition, the site of implantation appears to affect device output. These results provide additional support for intrapa-renchymal delivery of L-dopa and dopamine via polymer encapsulation as a possible treatment for PD.

Continued presence of intrastriatal but not intraventricular polymer-encapsulated PC12 cells is required for alleviation of behavioral deficits in Parkinsonian rodents.

To date, few studies have systematically evaluated the most appropriate location for grafting catecholaminergic cells as a potential treatment for Parkinson's disease (PD). The following study was conducted to determine 1) if placement of catecholamine-secreting encapsulated PC12 cells into the lateral ventricle of 6-OHDA-treated rats is as effective as intrastriatal implants on reducing apomorphine-induced rotational behavior, and 2) to determine if the survival of encapsulated PC12 cells is differentially affected by the implant site. Polymerencapsulated PC12 cells were implanted into either the striatum or lateral ventricle of unilateral 6-OHDA-lesioned rats. Animals were tested for apomorphine-induced rotations over a 6-wk period. Only those animals that received intrastriatal implants of encapsulated PC12 cells showed a reduction in rotation behavior. Moreover, removal of the devices from the striatum resulted in a return to preimplant rotation levels. Postexplant neurochemical analyses demonstrated that the potassium-evoked L-dopa device output increased in vivo while the potassium-evoked dopamine output from the devices decreased over time in vivo. The location of the implant significantly affected catecholamine output from the PC12 cell-loaded devices. The increase in potassium-evoked L-dopa output was greatest, as was the decrease in potassium-evoked dopamine output, from those devices implanted in the striatum. Basal output of dopamine and DOPAC was also significantly higher from devices explanted from the lateral ventricle. These results demonstrate that the continued presence of intrastriatal implants of encapsulated PC12 cells is required to maintain the behavioral effects in 6-OHDA-lesioned rats. In addition, the site of implantation appears to affect device output. These results provide additional support for intraparenchymal delivery of L-dopa and dopamine via polymer encapsulation as a possible treatment for PD.

Implantation of encapsulated catecholamine and GDNF-producing cells in rats with unilateral dopamine depletions and parkinsonian symptoms

Studies in rodents suggest that PC12 cells, encapsulated in semipermeable ultrafiltration membranes and implanted in the striatum, have some potential efficacy for the treatment of age- and 6-OHDA-induced sensorimotor impairments (22, 70, 71, 74). The objectives of this study were to: (1) determine if baby hamster kidney cells engineered to secrete glial cell line-derived neurotrophic factor (BHK-GDNF) would survive encapsulation and implantation in a dopamine-depleted rodent striatum, (2) compare polymer-encapsulated PC12 and PC12A cells in terms of their ability to survive and produce catecholamines in vivo in a dopamine-depleted striatum, and (3) determine if BHK-GDNF, PC12, or PC12A cells reduce parkinsonian symptoms in a rodent model of Parkinson's disease. Capsules with BHK-GDNF or PC12 cells contained viable cells after 90 days in vivo, with little evidence of host tissue damage/gliosis. In rats with tyrosine hydroxylase (TH)-positive fibers remaining in the lesioned striatum, there was TH-positive fiber ingrowth into the membranes of the BHK-GDNF capsules. PC12-containing capsules had higher basal release of both dopamine and L-DOPA after 90 days in vivo than before implantation, while basal release of both dopamine and L-DOPA decreased in the PC12A-containing capsules. Both encapsulated PC12 and PC12A cells, but not encapsulated BHK-GDNF cells, decreased apomorphine-induced rotations. Parkinsonian symptoms (akinesia, freezing/bracing, sensorimotor neglect) related to the extent of dopamine depletion were evident even in rats with dopamine depletions of only 25%. Evidence that encapsulated cells may attenuate these parkinsonian symptoms was not detected but most of the rats were more severely depleted of dopamine than Parkinson's patients (less than 2% dopamine remaining in the entire striatum), and these tests were not sensitive to differences between rats with less than 10% dopamine remaining. These results suggest that cell encapsulation technology can safely provide site-specific delivery of dopaminergic agonists or growth factors within the CNS, without requiring suppression of the immune system, and without using fetal tissue. Of the three types of encapsulated cells examined in the present study, PC12 cells seem to offer the most therapeutic potential in rats with severe dopamine depletions.

Intrastriatal implants of polymer-encapsulated PC12 cells: Effects on motor function in aged rats

1. 1. The feasibility of ameliorating the motor deficits in aged rats was evaluated in animals receiving polymer-encapsulated PC12 cells. 2. 2. Motor coordination and balance was evaluated in young (5–6 month) and aged (24–25 month) rats. Compared to the young animals, the aged animals fell more rapidly from a rotating rod and were unable to maintain their balance on a series of wooden beams of varying widths. 3. 3. Following baseline testing, aged animals received either no implant, empty capsules or PC12 cellloaded capsules implanted bilaterally into the striatum. 4. 4. Three weeks following surgery, animals were re-tested and a significant improvement in balance on the rotorod and wooden beams was observed in those aged animals receiving PC12 cell-loaded capsules. No improvements or decrements in performance were observed in those animals receiving empty. Histological analysis revealed the presence of surviving tyrosine hydroxylaseposidve PC12 cells randomly distributed within the capsules.

Functional Recovery in Hemiparkinsonian Primates Transplanted with Polymer-Encapsulated PC12 Cells

Cross-species neural grafting of cell lines immunoisolated by a permselective polymer membrane represents a promising source of neuroactive molecules for the treatment of neurodegenerative diseases. Utilization of a cell line of xenogeneic origin is advantageous since the transplanted cells will be rejected by the host immune system in case of breakage of the immunoisolating envelope. Polymer-encapsulated PC12 cells, a dopaminergic cell line derived from a rat pheochromocytoma, were transplanted in five Macaca fascicularis monkeys which had been previously rendered hemiparkinsonian by a unilateral carotid injection of 1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine. Well-preserved, tyrosine hydroxylase positive encapsulated PC12 cells were observed in the lesioned striatum for up to 5 months after implantation. Four out of five monkeys which received polymer-encapsulated PC12 cells showed significant behavioral improvement, whereas three monkeys implanted with either encapsulated bovine chromaffin cells or empty polymer envelopes showed no amelioration.

Polymer-Encapsulated PC12 Cells Promote Recovery of Motor Function in Aged Rats

The feasibility of using polymer-encapsulated PC12 cells to ameliorate the motor deficits in aged rats was evaluated. Spontaneous locomotion and motor coordination was evaluated in young (5-6 month) and aged (24-25 month) rats. Aged animals tested for spontaneous locomotor activity in Digiscan animal activity monitors were found to be hypoactive relative to young animals. Compared to the young animals the aged animals: (1) remained suspended from a horizontal wire for less time, (2) were unable to descend a wooden pole covered with wire mesh in a coordinated manner, (3) fell more rapidly from a rotating rod, and (4) were unable to maintain their balance on a series of wooden beams with either a square or rounded top of varying widths. Prior to implantation PC12 cell-loaded capsules were chromatographically characterized for catecholamine release. Following baseline testing, aged animals received either no implant, empty capsules, or PC12 cell-loaded capsules implanted bilaterally into the striatum. Three weeks following surgery, animals were retested and a significant improvement in balance on the rotorod and wooden beams was observed in those aged animals receiving PC12 cell-loaded capsules. No recovery was observed in the animals receiving PC12 cell-loaded capsules on any of the other motor tasks. Likewise, no improvement was observed on any behavioral measure in those animals receiving empty capsules. Histological analysis revealed the presence of numerous surviving tyrosine hydroxylase-positive PC12 cells within the capsules. Encapsulated PC12 cells survive following implantation into aged rats and such a technique may be useful for treating some of the behavioral consequences of aging.

Growth of tumour cell lines in polymer capsules: ultrastructure of encapsulated PC12 cells.

Recent studies indicate that polymer-encapsulated PC12 cells release sufficient amounts of dopamine to significantly alter behavioural paradigms in animals with unilateral lesions of dopaminergic midbrain neurons. Because cell fine structure provides a useful measure for assessment of storage function, exocytosis, metabolism, cell activity and cell viability, we examined the ultrastructure of PC12 cells grown in semi-permeable polymer capsules maintained in vitro or implanted into the forebrain of rats or guinea pigs. Encapsulated PC12 cells remained viable and continued to divide for the entire evaluation period of six months. Overall morphologies of encapsulated PC12 cells were similar in both environments and they resembled PC12 cells grown in monolayer cultures. In short-term cultures, encapsulated PC12 cells typically contained abundant quantities of chromaffin cell-like granules. The encapsulated cells had initially abundant microvilli on their surfaces which decline in frequency over time. After long-term enclosure for ten weeks or more, fewer secretory granules were detected in the cytoplasm of cells in capsules cultured in vitro and in brain-implanted capsules. Some cells in implanted capsules had long slender filipodia that were not present on PC12 cells in cultured capsules. The morphological changes of PC12 cells may correlate with altered growth conditions such as serum and oxygen concentrations, the presence or absence of growth factors in different environments, and with changes of cell interactions related to cell densities and build up of debris within the capsules over time. Since dopaminergic PC12 pheochromocytoma cells remain viable in semi-permeable polymer capsules for at least six months, such 'cell-capsules' could provide an alternative to dopamine-secreting embryonic neural grafts in dopamine replacement therapies.

Polymer-encapsulated PC12 cells: long-term survival and associated reduction in lesion-induced rotational behavior.

Intrastriatal implantation of a dopaminergic cell line surrounded by a permeable, thermoplastic membrane was investigated as a method of long-term dopamine (DA) delivery within the central nervous system (CNS). An increase in DA release from PC12 cell-loaded capsules maintained in vitro was associated with an increase in mitotic activity of the encapsulated cell line. A significant reduction in apomorphine-induced rotational behavior was observed after PC12 cell-containing capsules were implanted into unilaterally 6-hydroxydopamine (6-OHDA) lesioned rats, which was sustained for 24 wk. Four wk after implantation, microdialysis studies revealed the presence of DA near PC12 cell-containing capsules, which was comparable to extracellular striatal levels of unlesioned controls. Extracellular striatal DA was undetectable by microdialysis in lesioned animals near empty polymer capsules. Histological analysis after 24 wk in vivo demonstrated that encapsulated PC12 cells survived, continued to express tyrosine hydroxylase, and that encapsulation prevented tumorigenesis. The data suggested that the release of a diffusible substance, most likely DA, from an implant is sufficient to exert a long-term functional influence upon 6-OHDA unilaterally lesioned rats and that capsules containing DA-secreting cells may be an effective method of long-term DA delivery in the CNS.

Long-term cross-species brain transplantation of a polymer-encapsulated dopamine-secreting cell line

Cross-species transplantation of dopamine-releasing cell lines protected against immune rejection by a semipermeable synthetic membrane may provide a source of neurotransmitters for the treatment of Parkinson's disease. Experiments were carried out to assess whether polymer-encapsulated PC12 cells, a catecholaminergic cell line derived from a rat pheochromocytoma, could survive in vitro as well as in vivo after implantation in the striatum of adult guinea pigs. When maintained in vitro, the encapsulated PC12 cells exhibited good survival, proliferated, and spontaneously released dopamine for at least 6 months. They also retained the capacity for depolarization-elicited dopamine release. In vivo, well-preserved tyrosine hydroxylase-positive PC12 cells were observed in capsules implanted for 4, 8, and 12 weeks. Unencapsulated PC12 cells or cells in nonintact capsules did not survive transplantation at any of these time periods. The survival of encapsulated PC12 cells transplanted across species suggests that polymer encapsulation may provide an alternative for xenotransplantation of secretory cells in the absence of systemic immunosuppression.