Protein delivery by microencapsulated cells

Sweat gland regeneration: Current strategies and future opportunities

For patients with extensive skin defects, loss of sweat glands (SwGs) greatly decreases their quality of life. Indeed, difficulties in thermoregulation, ion reabsorption, and maintaining fluid balance might render them susceptible to hyperthermia, heatstroke, or even death. Despite extensive studies on the stem cell biology of the skin in recent years, in-situ regeneration of SwGs with both structural and functional fidelity is still challenging because of the limited regenerative capacity and cell fate control of resident progenitors. To overcome these challenges, one must consider both the intrinsic factors relevant to genetic and epigenetic regulation and cues from the cellular microenvironment. Here, we describe recent progress in molecular biology, developmental pathways, and cellular evolution associated with SwGdevelopment and maturation. This is followed by a summary of the current strategies used for cell-fate modulation, transmembrane drug delivery, and scaffold design associated with SwGregeneration. Finally, we offer perspectives for creating more sophisticated systems to accelerate patients' innate healing capacity and developing engineered skin constructs to treat or replace damaged tissues structurally and functionally.

CHO immobilization in alginate/poly-L: -lysine microcapsules: an understanding of potential and limitations

Microencapsulation offers a unique potential for high cell density, high productivity mammalian cell cultures. However, for successful exploitation there is the need for microcapsules of defined size, properties and mechanical stability. Four types of alginate/poly-L: -Lysine microcapsules, containing recombinant CHO cells, have been investigated: (a) 800 mum liquid core microcapsules, (b) 500 mum liquid core microcapsules, (c) 880 mum liquid core microcapsules with a double PLL membrane and (d) 740 mum semi-liquid core microcapsules. With encapsulated cells a reduced growth rate was observed, however this was accompanied by a 2-3 fold higher specific production rate of the recombinant protein. Interestingly, the maximal intracapsular cell concentration was only 8.7 x 10(7) cell mL(-1), corresponding to a colonization of 20% of the microcapsule volume. The low level of colonization is unlikely to be due to diffusional limitations since reduction of microcapsule size had no effect. Measurement of cell leaching and mechanical properties showed that liquid core microcapsules are not suitable for continuous long-term cultures (>1 month). By contrast semi-liquid core microcapsules were stable over long periods with a constant level of cell colonization (varphi = 3%). This indicates that the alginate in the core plays a predominant role in determining the level of microcapsule colonization. This was confirmed by experiments showing reduced growth rates of batch suspension cultures of CHO cells in medium containing dissolved alginate. Removal of this alginate would therefore be expected to increase microcapsule colonization.

Superior Cell Delivery Features of Poly(ethylene glycol) Incorporated Alginate, Chitosan, and Poly-l-lysine Microcapsules

Microencapsulation is an emerging technology in the development of bioartificial organs for drug, protein, and delivery systems. One of the advancements in establishing an appropriate membrane material for live cell and tissue encapsulation is the incorporation of poly(ethylene glycol) (PEG) to the widely studied alginate microcapsules. The current study investigates the properties of integrating PEG to microcapsules coated with poly-L-lysine (PLL) and chitosan as well as a novel microcapsule membrane which combines both PLL and chitosan. Results show that microcapsules containing PEG can support cell viability and protein secretion. The addition of PEG to PLL and chitosan-coated microcapsules improves the stability of microcapsules when exposed to a hypotonic solution. We also compared the novel microcapsule with two other previously used microcapsules including alginate-chitosan-PEG and alginate-PLL-PEG-alginate. Results show that all three membranes are capable of providing immunoprotection to the cells and have the potential for long-term storage at -80 degrees C. The novel membrane containing PEG, chitosan, and PLL, however, revealed the highest cell viability and mechanical strength when exposed to external rotational force, but it was unable to sustain osmotic pressure. The study revealed the potential of using PEG-incorporated alginate, chitosan, and PLL microcapsules for encapsulating live cells producing proteins and hormones for therapy.

Formulation and characterization of calcium alginate beads containing ampicillin

The purpose of this work was the preparation and characterization of calcium alginate beads containing ampicillin. Aqueous solutions of drug and sodium alginate (three viscosity grades) were added drop by drop to aqueous solutions of calcium chloride; the droplets instantaneously formed gel beads, which were then dried. Morphological studies and drug contents, in vitro release, and erosion tests were carried out for the characterization of the prepared beads. The dried particles were characterized by irregular shape and a smooth or rough surface, depending on the viscosity grade of the alginate used. The control of the drug for different time intervals depended on the molecular weight of the polymer used; however, the pH-change test showed that this capacity was much lower in the case of acid-treated particles. The results obtained show that the ampicillin beads prepared are suitable for intramammary therapy.

Dopamine secretion by PC12 cells microencapsulated in a hydroxyethyl methacrylate--methyl methacrylate copolymer

A rat pheochromocytoma cell line (PC12) was encapsulated in a water-insoluble hydroxyethyl methacrylate-methyl methacrylate copolymer by interfacial precipitation from a polyethylene glycol 200 solution into phosphate-buffered saline. The resulting capsules (660 +/- 44 microns in diameter; 84 +/- 27 microns wall thickness) contained viable PC12 cells in a spheroidal arrangement, much like tumour spheroids, the latter grown on surfaces unsuitable for cell attachment. In these spheroids, the viable cells formed a band approximately 100 microns thick, surrounding an inner core of necrotic cells. A similar arrangement was seen 14, 28 and 42 days after encapsulation, with capsules maintained in an in vitro tissue culture environment; the annular ring was roughly constant in size, although the packing density appeared to increase over the 6 week observation period. During the first 4 weeks, when measurements were made the encapsulated cells converted a tetrazolium dye (MTT) into an insoluble formazan product, in a time-after-encapsulation-dependent manner. This indicated that PC12 cells retained viability despite encapsulation and an ability to increase (at least in part) their metabolic capacity, presumably by a combination of proliferation and altered cellular activity. The encapsulated PC12 cells also secreted dopamine when incubated in a high potassium release medium but not in a low potassium, conventional tissue culture medium (RPMI 1640). Consistent with the MTT results, the amount of dopamine released was also dependent on the time after encapsulation, as well as the cell density at the time of encapsulation.