Patrick A. Tresco

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 semi-permeable synthetic membrane may provide a source of neurotransmitters for the treatment of Parkinsons 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.

Behavioral recovery following intrastriatal implantation of microencapsulated PC12 cells

The motor deficits associated with Parkinsons disease may be ameliorated by intrastriatal placement of dopamine-secreting cells in a polymer capsule. Water soluble polyelectrolytes were utilized for membrane encapsulation of dopamine-secreting PC12 cells. Membrane permeability studies revealed exclusion of radiolabeled 69,000 Da albumin, whereas 30,000 Da carbonic anhydrase was able to cross the membrane. No cytolytic activity was observed following incubation of the encapsulated PC12 cells with PC12 cell-directed antiserum and fresh complement. In vitro, dopamine release and the surface area of intact cells per microcapsule, reached a plateau at 4 weeks that was maintained for at least 12 weeks. Viable PC12 cells were observed in microcapsules implanted for 4 and 8 weeks in nonlesioned guinea pig striata. The behavioral effect of intrastriatal dopamine release from microencapsulated PC12 cells was evaluated in the 6-hydroxydopamine unilaterally lesioned rat model. From 1 to 4 weeks postimplantation a significant reduction in rotation behavior under apomorphine challenge was observed with PC12 cell-loaded microcapsules as compared to empty microcapsules. Tyrosine hydroxylase immunopositive PC12 cells were observed 4 weeks postimplantation in all animals exhibiting a reduction in turning behavior. Implantation of polymer-encapsulated cells may provide a means for long-term delivery of neurotransmitters and growth factors to the nervous system.

An encapsulated dopamine-releasing polymer alleviates experimental parkinsonism in rats

The effect of sustained intrastriatal release of dopamine (DA) from polymer matrices on apomorphine-induced turning behavior in a 6-hydroxydopamine (6-OHDA) unilaterally lesioned rat model was analyzed. A biocompatible semipermeable tube was placed in a denervated striatum as a receptacle for DA-releasing polymer rods. In vitro kinetics showed sustained release of DA from a polymeric rod for 15 days. Implantation of a DA-releasing rod within the striatal receptacle significantly decreased apomorphine-induced rotational behaviour in lesioned animals. Upon removal of the DA-releasing system from the receptacle, rotational behaviour increased within 2 weeks and approached preimplant control values 4 weeks later. Acute microdialysis revealed that DA appeared in the extracellular space within 20 min after the implantation of a DA-releasing rod into a denervated striatum. Significant DA amounts were still measurable 7 days postimplantation, indicating sustained DA release from the polymer rod. Dopamine released from a polymer matrix through a semipermeable receptacle alleviates experimental parkinsonism in rats, suggesting that controlled intrastriatal release of DA from a polymer matrix may provide an alternative method for the treatment of Parkinsons disease.

Macroencapsulation of dopamine-secreting cells by coextrusion with an organic polymer solution

A new method of coextruding living cells in the core of a forming hollow fibre is described. PC12 cells, an immortalized cell line which secretes large amounts of dopamine, and dissociated bovine adrenal chromaffin cells, a non-dividing cell type which also secretes dopamine, were coextruded by a dry-jet wet spinning technique through a double-lumen spinneret from a 15% weight by volume solution of poly(acrylonitrile vinyl chloride) in either dimethylsulphoxide (DMSO), dimethylacetamide (DMAC) or dimethylformamide (DMF). Closure of the fibre was achieved by mounting polytetrafluoroethylene tubes on a rotating coaxial wheel system which squeezed the forming hollow fibre at regular intervals. Spontaneous and potassium-stimulated release of catecholamines from the macrocapsules were quantified under static conditions by ion-pair reverse-phase high-performance liquid chromatography equipped with electrochemical detection at 2, 4 and 6 wk. At all time periods, coextruded macrocapsules with either PC12 cells or adrenal chromaffin cells released dopamine under either unstimulated or stimulated conditions. An increase over time in dopamine release was observed from PC12 cell coextruded macrocapsules with observable difference between capsules extruded with DMSO, DMAC or DMF as solvents. Well-preserved PC12 cells and adrenal chromaffin cells were present in coextruded macrocapsules with no observable difference between capsules extruded with DMSO, DMAC or DMF as inocuity of macroencapsulation by coextrusion from an organic polymer solution. Owing to the particular fluid dynamics of this technique, minimal potentially toxic cell-solvent contact occurs allowing the use of a wider range of water-insoluble polymeric systems.(ABSTRACT TRUNCATED AT 250 WORDS)

Transplantation of microencapsulated bovine chromaffin cells reduces lesion-induced rotational asymmetry in rats.

Surrounding bovine chromaffin cells by a semipermeable membrane may protect the transplanted cells from a host immune response and shield them from the inflammatory process resulting from the surgical trauma. Encapsulation of the chromaffin cells was achieved by interfacial adsorption of a polycation on a polyanionic colloid matrix in which the chromaffin cells were entrapped. Basal and potassium-evoked release of catecholamines from encapsulated bovine chromaffin cells was analyzed over a 4-week period in vitro. Norepinephrine and dopamine release remained constant over time whereas epinephrine release significantly decreased. The chromaffin cells also retained the capacity for depolarization-elicited catecholamine release 4 weeks following the encapsulation procedure. Morphological analysis revealed the presence of intact chromaffin cells with well-preserved secretory granules. Striatal implantation of chromaffin cell-loaded capsules significantly reduced apomorphine-induced rotation compared to empty polymer capsules in animals lesioned with 6-hydroxydopamine for at least 4 weeks. Intact chromaffin cells expressing tyrosine hydroxylase and dopamine-beta-hydroxylase were observed in all capsules implanted in the striatum for 4 weeks. The assessment of the clinical potential of transplanting encapsulated adrenal chromaffin cells of either allo- or xenogeneic origin for Parkinsons disease will require long-term behavioral studies. The present study suggests, however, that the polymer encapsulation procedure may offer an alternative to adrenal autografts as a source of dopaminergic tissue.

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, micro-dialysis 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.

Transplantation of polymer encapsulated neurotransmitter secreting cells: effect of the encapsulation technique.

Deficits associated with neurological diseases may be improved by the transplantation within the brain lesioned target structure of polymer encapsulated cells releasing the missing neurotransmitter. Surrounding cells with a permselective membrane of appropriate molecular weight cut-off allows inward diffusion of nutrients and outward diffusion of neurotransmitters, but prevents immunoglobulins or immune cells from reaching the transplant. This technique therefore allows transplantation of post-mitotic cells across species. It also permits neural grafting of transformed cell lines since the polymer capsule prevents the formation of tumors by physically sequestering the transplanted tissue. In the present study, we compared the ability of dopamine-secreting cells, encapsulated by 2 different methods, to reverse experimental Parkinsons disease, a neurodegenerative disease characterized by motor disturbances due to a lack of dopamine within the striatum following degeneration of the dopaminergic nigro-striatal pathway. PC12 cells were loaded in polyelectrolyte-based microcapsules or thermoplastic-based macrocapsules and maintained in vitro or transplanted in a rat experimental Parkinson model for 4 weeks. Chemically-induced depolarization increased the in vitro release of dopamine from macrocapsules over time, while no increase in release was observed from microcapsules. Encapsulated PC12 cells were able to reduce lesion-induced rotational asymmetry in rats for at least 4 weeks, regardless of the encapsulation technique used. With both encapsulation methods, PC12 cell viability was greater in vivo than in vitro which suggests that the striatum releases trophic factors for PC12 cells. More brain tissue damage was observed with microcapsules than macrocapsules, possibly the result of the difficulty of manipulating the more fragile microcapsules.(ABSTRACT TRUNCATED AT 250 WORDS)

Polymer encapsulated dopaminergic cell lines as "alternative neural grafts".

Our preliminary findings (Jaeger et al., 1988; Aebischer et al., 1989; Tresco et al., 1989) and the studies in progress show that encapsulated dopaminergic cell lines survive enclosure within a semi-permeable membrane. The encapsulated cells remained viable for extended time periods when maintained in vitro. Moreover, encapsulated PC12 and T28 cells have the potential to survive following their implantation into the forebrain of rats. Cell lines are essentially immortal because they continue to divide indefinitely. This property allows perpetual self-renewal of a given cell population. However, the capacity of continuous uncontrolled cell division may also lead to tumor formation. This in fact is the case for unencapsulated PC12 cell implants placed into the brain of young Sprague Dawley rats (Jaeger, 1985). Cell line encapsulation has the potential to prevent tumor growth (Jaeger et al., 1988). Survival for 6 months in vitro suggests that encapsulation does not preclude long-term maintenance of an homogeneous cell line like PC12 cells. The presence of mitotic figures in the capsules further supports the likelihood of propagation and self renewal of the encapsulated population. Another significant property of cell lines is that they consist of a single, genetically homogeneous cell type. They do not require specific synaptic interactions for their survival. In the case of PC12 and T28 lines, the cells synthesize and release neurotransmitters. Our data show that PC12 and T28 cells continue to release dopamine spontaneously and to express specific transmitters and enzymes following encapsulation. Thus, cell lines such as these may constitute relatively simple neural implants exerting their function via humoral release.(ABSTRACT TRUNCATED AT 250 WORDS)

Repair of the blood-brain barrier following implantation of polymer capsules

Past studies of polymer-encapsulated cell lines implanted in the brain indicated their usefulness for transmitter replacement therapy in animal models. Such grafts may have potentially important clinical applications, but their placement into neural parenchyma may cause a traumatic injury resulting in a leaky blood-brain barrier around the implant. This study investigated whether or not injury repair and reformation of the barrier takes place near a polymer capsule implanted in the brain of Sprague-Dawley rats. The two methods used for detection of a leaky barrier were immunocytochemical localization of extravasated serum albumin and circulating Evans blue that binds to serum albumin. Immunocytochemical staining for glial filament protein provided a measure for evaluating injury associated gliosis. Polymer capsules implanted for 10, 16 and 18 days were surrounded by microvessels that leaked detectable quantities of serum albumin into interstitial spaces and, by secondary uptake, into some nearby neurons and reactive astrocytes. Reactive astroglia were observed within the outer regions of the capsule wall and in the near vicinity of the implant after these early survival times. In contrast, at post-implantation times of 46 and 54 days, serum albumin was no longer detected in the neural parenchyma near the macrocapsules and only few reactive astrocytes remained. These findings show that polymer capsules implanted within the cerebrum permit (a) reformation of the blood-brain barrier and (b) occurrence of repair processes that lead to minimal deposition of reactive astroglia near the implanted polymer capsule.

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

SummaryRecent 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 maintainedin 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 culturedin vitro and in brain-implated 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.