Simultaneous Immunofluorescent Detection of Coentrapped Cells in Gel Beads

An immunofluorescent method involving double color labeling and confocal microscopy was reported to specifically detect lactic acid bacteria and probiotic cells coimmobilized in gels beads. The method described is rapid (4 h) and sensitive and may be useful for studying cell dynamics during mixed-culture starter production using immobilized cells in gel beads. Microscopic observations were perfectly correlated to cell counts obtained using a sandwich enzyme-linked immunosorbent assay.     

Capture of rare cells in suspension with antibody-coated polystyrene beads

A method for the separation of one cell type present in small number from a predominant mixture of cell types using macroscopic polystyrene beads is demonstrated. An antibody specific to murine leukocytes (CD45) was adsorbed to the surface of the beads. Beads and murine hybridoma B cells were placed in test tubes and periodically inverted at fixed time intervals, causing the beads to settle through the suspension under creeping flow conditions. Capture was dependent upon interception: the captured cells must have traveled along streamlines that brought them to within a cell radius of the bead surface. B cells attached to 99-micrometer beads (maximum shear rate 8.1 s-1) were captured with greater efficiency but in lesser quantity than those attached to 170-micrometer beads (maximum shear rate 13.9 s-1). Cell capture unexpectedly reached a plateau in less than 2 h, a phenomenon that appears to involve changes in both the cells and the beads. Capture of cells was effective out to dilutions of 1:10 000 with purity in the captured population of better than 74%. This method allows for the study of physical parameters important for cell attachment and capture as well as for practical separation of rare cells.     

Oxygen diffusivity in gel beads containing viable cells

This article proposes a simple steady-state method for measuring the effective diffusion coefficient of oxygen (D(e)) in gel beads entrapping viable cells. We applied this method to the measurement of D(e) in Ca- and Ba-alginate gel beads entrapping Saccharomyces cerevisiae and Pseudomonas ovalis. The diffusivity of oxygen through gel beads containing viable cells was measured within an accuracy of +/-7% and found not to be influenced by cell density (0-30 g/L gel), cell type, and cell viability in gel beads. The oxygen diffusivity in the Ca-alginate gel beads was superior to that of the Ba-alginate gel beads, and the D(e) in the Ca-alginate gel beads nearly equalled the molecular diffusion coefficient in the liquid containing the gel beads. The oxygen concentration profile in a single Ca-alginate gel bead was calculated and compared to the distribution of mycelia of Aspergillus awamori grown in that gel bead. This procedure indicated that the oxygen concentration profile is useful for the estimation of the thickness of the cell layer in a gel bead. Numerical investigation revealed that high effectiveness factors, greater than 0.8, could be obtained using microgel beads with a radius of 0.25 mm.     

Lactococcus lactis release from calcium alginate beads.

Cell release during milk fermentation by Lactococcus lactis immobilized in calcium alginate beads was examined. Numbers of free cells in the milk gradually increased from 1 x 10(6) to 3 x 10(7) CFU/ml upon successive reutilization of the beads. Rinsing the beads between fermentations did not influence the numbers of free cells in the milk. Cell release was not affected by initial cell density within the beads or by alginate concentration, although higher acidification rates were achieved with increased cell loading. Coating alginate beads with poly-L-lysine (PLL) did not significantly reduce the release of cells during five consecutive fermentations. A double coating of PLL and alginate reduced cell release by a factor of approximately 50. However, acidification of milk with beads having the PLL-alginate coating was slower than that with uncoated beads. Immersing the beads in ethanol to kill cells on the periphery reduced cell release, but acidification activity was maintained. Dipping the beads in aluminum nitrate or a hot CaCl2 solution was not as effective as dipping them in ethanol. Ethanol treatment or heating of the beads appears to be a promising method for maintaining acidification activity while minimizing viable cell release due to loosely entrapped cells near the surface of the alginate beads.     

Lactococcus lactis release from calcium alginate beads.

Cell release during milk fermentation by Lactococcus lactis immobilized in calcium alginate beads was examined. Numbers of free cells in the milk gradually increased from 1 x 10(6) to 3 x 10(7) CFU/ml upon successive reutilization of the beads. Rinsing the beads between fermentations did not influence the numbers of free cells in the milk. Cell release was not affected by initial cell density within the beads or by alginate concentration, although higher acidification rates were achieved with increased cell loading. Coating alginate beads with poly-L-lysine (PLL) did not significantly reduce the release of cells during five consecutive fermentations. A double coating of PLL and alginate reduced cell release by a factor of approximately 50. However, acidification of milk with beads having the PLL-alginate coating was slower than that with uncoated beads. Immersing the beads in ethanol to kill cells on the periphery reduced cell release, but acidification activity was maintained. Dipping the beads in aluminum nitrate or a hot CaCl2 solution was not as effective as dipping them in ethanol. Ethanol treatment or heating of the beads appears to be a promising method for maintaining acidification activity while minimizing viable cell release due to loosely entrapped cells near the surface of the alginate beads.     

Cell surface action of thrombin is sufficient to initiate division of chick cells

Thrombin covalently linked to carboxylate-modified polystyrene beads initiated division of quiescent chick embryo (CE) cells either in medium containing low levels of serum or in serum-free medium. Release of thrombin was monitored by measuring acid-precipitable radioactivity released from 125I-thrombin beads into the medium during incubation with cells. Even if all of the acid-precipitable material released from the beads were active thrombin, it was not sufficient to account for any of the observed cell division, and was 10-30 fold less than the amount necessary to produce the increase in cell number caused by the thrombin beads. Two other kinds of experiments also showed that material released into the medium did not account for the observed initiation of cell division. First, medium taken from cultures incubated with thrombin beads did not initiate cell division when added to new quiescent cultures. Second, in coverslip experiments where populations of cells with an without thrombin feads shared the same medium, only bead-contacted cells divided. Several results suggested that the material which was released from the thrombin beads resulted from cell-associated proteolysis rather than from "leakage" of intact thrombin from the beads. For example, after incubating 125I-thrombin beads with or without CE cells, we were unable to detect any intact thrombin released into the medium. In addition, most of the material released from the beads was acid-soluble and was only released in the presence of CE cells. A few thrombin beads were endocytosed by CE cells, but they were surrounded by an intact plasma membrane. Thus they did not directly interact with the cytoplasm. The close association of many of the beads with the cell surface and the presence of a few beads in endocytic vesicles made it important to consider the possibility that thrombin might be released from the beads directly into the cells. This possibility was explored using ultrastructural (EM) autoradiography. With this technique (where one grain represented 700--900 thrombin molecules), we found that beads inside the cells had approximately the same number of grains as beads not in contact with cells. This suggested that little, if any, additional radioactive material had been released from the beads which were in contact with the cells. In addition, we were unable to detect any grains in the cytoplasm which could be attributed to released thrombin, even using an amount of 125I-thrombin beads which was 8 fold greater than the amount which produced maximal cell division. Taken together, these results provide direct evidence that thrombin action at the cell surface is sufficient to initiate division of CE cells.     

Estimation of cell surface associated protease activity and its application to lymphocytes

A new method has been developed to estimate proteolytic activity available at the cell surface. Radioiodinated protein substrates are covalently linked to modified polystyrene-divinylbenzene beads with various diameters. These beads are presented to viable cells. Secreted enzyme activity is estimated when no contact occurs between beads and cells. Surface associated proteolytic activity is estimated by the increased rate of iodinated peptide release due to a contact between beads and cells. This method was applied to various lymphocyte preparations. In the absence of serum, mouse spleen lymphocytes produce three- to fourfold higher proteolytic activity than lymph node cells. This activity is completely inhibited by serum diluted 1:10. Since the proteolysis is so marked in the case of spleen cells, one must conclude that lymphocytes removed from the serum and treated in buffered mediums at 37° C have enzymatically altered surface properties. Cell surface associated enzyme activity was measured using rat lymph node lymphocytes with less than 0.1% contamination by granulocytes. This predominantly thymus derived, T cell population had 30% increase in proteolysis due to contact between cells and solid-phase localized substrate of casein. The released enzymatic activity was inhibited by diisopropylfluorophosphate, but its effect on the surface associated enzyme activity remains questionable since it perturbs several membrane functions.     

Localized transfection with magnetic beads coated with PCR products and other nucleic acids

The bead transfection method involves binding nucleic acids onto 3-microm-diameter paramagnetic beads, treating the beads with transfection reagent, and using them as scaffolds to direct transfection to individual cells or regions in a population. Typically, PCR products are used because they can be conveniently generated using biotinylated primers and can introduce site-directed mutations, without the need for cloning or plasmid purification. However, the method can be adapted to transfect plasmid DNA or RNA. The magnetic properties of the beads allows magnets to direct the loci of transfection in cell culture; magnetic arrays are built in cell culture chambers to allow multiple parallel transfections on the same microscope coverslip. The PCR reaction and transfection can be carried out in 1 d, and transfection results can be viewed in 24-48 h.     

Immobilization of Pseudomonas delafieldii with magnetic polyvinyl alcohol beads and its application in biodesulfurization

Pseudomonas delafieldii was immobilized in magnetic polyvinyl alcohol (PVA) beads using a hydrophilic magnetic fluid, which was prepared by a co-precipitation method. The beads had distinct super-paramagnetic properties and were compared with immobilized cells in non-magnetic PVA beads. Their desulfurizing activity was increased slightly from 8.7 to 9 mmol sulfur kg(-1) (dry cell) h(-1). The main advantages was that the magnetic immobilized cells maintain a high desulfurization activity and remain in good shape after 7 times of repeated use, while the non-magnetic immobilized cells could only be used for 5 times. Furthermore, the magnetic immobilized cells could be easily collected or separated magnetically from the biodesulfurization reactor.     

Fabrication of hyaluronic acid hydrogel beads for cell encapsulation

Hyaluronic acid (HA) hydrogel beads were prepared by photopolymerization of methacrylated HA and N-vinylpyrrolidone using alginate as a temporal spherical mold. Various fabrication conditions for preparing the hydrogel beads, such as the concentration of methacrylated HA and UV irradiation time, were optimized to control swelling properties and enzymatic degradability. A new concept for cell encapsulation is proposed in this paper. Viable cells were directly injected into the hydrogel beads using a microinjection technique. When bovine articular chondrocytes were injected into HA hydrogel beads and cultivated for 1 week, the cells could proliferate well within the HA beads. HA hydrogel beads could be potentially used as injectable cell delivery vehicles for regenerating tissue defects.     

Spectrophotometric quantification of lactic bacteria in alginate and control of cell release with chitosan coating

Lactococcus lactis ssp. cremoris was entrapped within a Ca-alginate matrix, and an in situ spectrophotometric method for monitoring cell population in calcium alginate beads described. The intracapsular cell population can be estimated by measuring the optical density of beads containing cells, using cell-free beads as reference, or by measuring absorbance of a liquified bead suspension. Alginate beads, and beads coated with chitosan type I, II, and I and II mixtures, were examined for cell release. Lower viscosity chitosan (type I) coatings reduced cell release by a factor of 100 from10⁵ cfu ml⁻¹ to 10³ cfu ml⁻¹ after 6 h of fermentation. Reuse of chitosan I coated alginate beads also showed a reduction in cell release by a factor of 100. Cell loading and initial cell growth within the beads greatly affected cell release. Reducing the initial cell release would lower the overall levels of cell release throughout the fermentation. Compared to non-immobilized cultures, a 20–40% reduction in the lactic acid production rate was observed for alginate beads and chitosan I coated alginate beads, respectively. This reduction can be compensated for by increasing the intracapsular cell loading during immobilization, or before the onset of fermentation.     

Development of a microchannel emulsification process for pancreatic beta cell encapsulation

In this study, we developed a high-throughput microchannel emulsification process to encapsulate pancreatic beta cells in monodisperse alginate beads. The process builds on a stirred emulsification and internal gelation method previously adapted to pancreatic cell encapsulation. Alginate bead production was achieved by flowing a 0.5–2.5% alginate solution with cells and CaCO₃ across a 1-mm thick polytetrafluoroethylene plate with 700 × 200 μm rectangular straight-through channels. Alginate beads ranging from 1.5–3 mm in diameter were obtained at production rates exceeding 140 mL/hr per microchannel. Compared to the stirred emulsification process, the microchannel emulsification beads had a narrower size distribution and demonstrated enhanced compressive burst strength. Both microchannel and stirred emulsification beads exhibited homogeneous profiles of 0.7% alginate concentration using an initial alginate solution concentration of 1.5%. Encapsulated beta cell viability of 89 ± 2% based on live/dead staining was achieved by minimizing the bead residence time in the acidified organic phase fluid. Microchannel emulsification is a promising method for clinical-scale pancreatic beta cell encapsulation as well as other applications in the pharmaceutical, food, and cosmetic industries.     

Poly-N-vinylcaprolactam gel: A novel matrix for entrapment of microorganisms

Summary A new gel-type support poly-N-vinylcaprolactam for microbial cell immobilization is presented. The method allows one to obtain beads of biocatalyst in a single step. The properties of beads obtained using different types of gel stabilizers were compared; the best stabilizer was found to be tannin. The method developed was used for entrapment of viable bacterial cells and fungal spores. The biocatalysts obtained were used for transformations of both hydrophilic (sorbitol, indolyl-3-acetic acid) and lipophilic (cortexolone, hydrocortisone) substrates.Abbreviations PVC poly-N-vinylcaprolactam - ImC immobilized cells - IAA indolyl-3-acetic acid - TLC thin layer chromatography     

Factors that affect the efficiency of cell transfection by immunoporation

Immunoporation is a recently discovered method that is able to transfect various human cell lines efficiently by targeting the cell surface antigens with antibody-coated beads. For this particular study, HL60, a cell line difficult to transfect by other methods, was used as a model to define the various parameters of the cell membrane that determine the efficiency of this method. The level of antigen expression on the cell surface was the first parameter to be analyzed and experiments indicated that there is a close correlation between the level of expression of surface antigens and the efficiency of immunoporation. The mixing speed, the bead to cell ratio, and the mixing time were all found to affect the ability of the antigen-coated beads to pull holes in the cells and it was found that for HL60 cells the optimum mixing speed was 40 rpm and the bead to cell ratio was 20:1 using a mixing time of 6 h.     

Introducing Micrometer-Sized Artificial Objects into Live Cells: A Method for Cell–Giant Unilamellar Vesicle Electrofusion

Here, we report a method for introducing large objects of up to a micrometer in diameter into cultured mammalian cells by electrofusion of giant unilamellar vesicles. We prepared GUVs containing various artificial objects using a water-in-oil (w/o) emulsion centrifugation method. GUVs and dispersed HeLa cells were exposed to an alternating current (AC) field to induce a linear cell–GUV alignment, and then a direct current (DC) pulse was applied to facilitate transient electrofusion. With uniformly sized fluorescent beads as size indexes, we successfully and efficiently introduced beads of 1 µm in diameter into living cells along with a plasmid mammalian expression vector. Our electrofusion did not affect cell viability. After the electrofusion, cells proliferated normally until confluence was reached, and the introduced fluorescent beads were inherited during cell division. Analysis by both confocal microscopy and flow cytometry supported these findings. As an alternative approach, we also introduced a designed nanostructure (DNA origami) into live cells. The results we report here represent a milestone for designing artificial symbiosis of functionally active objects (such as micro-machines) in living cells. Moreover, our technique can be used for drug delivery, tissue engineering, and cell manipulation.     

Three-dimensional Alginate-bead Culture of Human Pituitary Adenoma Cells

A three-dimensional culture method is described in which primary pituitary adenoma cells are grown in alginate beads. Alginate is a polymer derived from brown sea algae. Briefly, the tumor tissue is cut into small pieces and submitted to an enzymatic digestion with collagenase and trypsin. Next, a cell suspension is obtained. The tumor cell suspension is mixed with 1.2% sodium alginate and dropped into a CaCl₂ solution, and the alginate/cell suspension is gelled on contact with the CaCl₂ to form spherical beads. The cells embedded in the alginate beads are supplied with nutrients provided by the culture media enriched with 20% FBS. Three-dimensional culture in alginate beads maintains the viability of adenoma cells for long periods of time, up to four months. Moreover, the cells can be liberated from the alginate by washing the beads with sodium citrate and seeded on glass coverslips for further immunocytochemical analyses. The use of a cell culture model allows for the fixation and visualization of the actin cytoskeleton with minimal disorganization. In summary, alginate beads provide a reliable culture system for the maintenance of pituitary adenoma cells.     

Magnetic beads (Dynabead™) toxicity to endothelial cells at high bead concentration: Implication for tissue engineering of vascular prosthesis

Magnetic beads (Dynabeads) have been used for the purification of endothelial cells. One application for this procedure may be for single-stage seeding of bypass grafts. The number of endothelial cells (EC) isolated is crucial and therefore to increase the number of cells extracted, a higher number of Dynabeads per cell may need to be used. The effect of large numbers of CD31 Dynabeads on cell proliferation/metabolism is unknown. We undertook this study using CD31-coated Dynabeads and EC from human umbilical vein. EC were coated at concentrations of 4, 10, or 50 beads per cell. The cells were cultured for 6 days with control being normal EC. Cellular proliferation was assessed by trypsinization of cells and metabolism assessed with an Alamar blue viability assay. In a further experiment a compliant polyurethane graft was single-stage seeded with both coated Dynabeads and normal EC. The results showed that using a higher number of beads per cell resulted in a reduction in cell proliferation and a reduction in cell metabolism. The total number of Dynabeads-coated cells in culture compared to controls (%) by day 6 were 30.7 +/- 2.56, 41.3 +/- 9.8 and 59.2 +/- 7.3 for 50, 10, and 4 beads per cell, respectively. The corresponding results for Alamar blue were 43.7 +/- 1.2, 61.8 +/- 1.4, and 72.1 +/- 4.3. The seeded grafts showed reduced metabolism with the Dynabeads-coated EC. In conclusion, high numbers of beads per cell have a late detrimental effect on cell proliferation and metabolism. Therefore for single-stage seeding lower numbers of Dynabeads will need to be used with resultant reduction in the number of available EC.     

Calcium alginate immobilized hybridomas grown using a fluidized-bed perfusion system with a protein-free medium

Hybridoma SPO1 cells were immobilized in calcium alginate beads and were further grown in a fluidized-bed perfusion system with a protein-free medium. The presence of serum in the steps of entrapment was shown to be helpful for the preservation of cell viability. Each step during immobilization was investigated with respect to the extent of cell damage caused. The immobilization process using small beads caused a lower cell viability initially but allowed a higher rate of cell growth subsequently, compared to those in large beads. In a perfusion system for the continuous production of monoclonal antibodies (MAb), the viable cell density reached 2×10⁷ cells per ml of beads with a viability of 40%. Compared with the cells in suspension culture, the immobilized SPO1 cells showed higher viable cell based specific rates of substrate uptake (glucose and glutamine) and of MAb production. A significant drop in the formation of lactate after the cell growth entered a steady state suggested a higher activity of the Tricarboxylic Acid Cycle in the cells when the cell density became high.     

An evaluation of lectin-mediated magnetic bead cell sorting for the targeted separation of enteric bacteria

Lectin-labelled magnetic beads were assessed and compared with antisera as an alternative approach for the targeted separation and isolation of enteric bacteria. Of the 16 lectins tested against a range of bacterial species, concanavalin A (conA) showed the greatest potential. Agglutination of bacterial cells in suspension using conA and methods for effective labelling of the magnetic beads with the lectin were optimized. ConA-labelled magnetic beads were compared with antibody-labelled beads for recovery of bacterial cells from pure or mixed laboratory cultures and from natural populations in river water. Recovered cell populations were free from environmental impurities and a high percentage of the culturable cells was extracted. Specific cell recovery was found to be variable, but the use of lectins offers some promise as an alternative cell discriminator.     

Enhancing cell survival of atrazine degrading Rhodococcus erythropolis NI86/21 cells encapsulated in alginate beads

AIMS: To develop a method to produce beads with encapsulated Rhodococcus erythropolis NI86/21 with high cell density, extended shelf life, ease of handling and good atrazine degradation capabilities in both liquid and in agricultural soil. METHODS AND RESULTS: Our findings show that the supplementary recovery step in nutrient broth media shortly after cell encapsulation facilitates cell survival in both wet and dry beads upon extended storage at 4 degrees C. Air drying has little or no impact on encapsulated R. erythropolis cell's ability to degrade atrazine in liquid or soil. Bead storage for periods extending up to 12 months at 4 degrees C did not affect the capacity of R. erythropolis encapsulated cells to degrade atrazine in either BMN or nonsterile soil extracts. Bentonite-amended beads formulated with 1% skim milk and exposed to the supplementary growth step, outperformed all other bead formats. These beads provided adequate numbers of vigorous R. erythropolis cells in either liquid or soil media to degrade atrazine. CONCLUSIONS: Supplementary growth in nutrient broth media immediately following cell encapsulation greatly enhances R. erythropolis cells survival in both wet and dry beads upon extended storage at 4 degrees C. Wet and dried beads have similar capacity for atrazine degradation, and their usefulness and appeal in agronomic practise will only be known after bioassay evaluation and successful demonstration at field scale using incurred residues. SIGNIFICANCE AND IMPACT OF THE STUDY: R. erythropolis NI86/21 encapsulated cells have the potential to reduce residual atrazine in soil, thereby minimizing the likelihood of off-site transport to ground or river water and reduce the loss of crops because of phytotoxicity of residual herbicide. Owing to their ease of handling, storage and possible compatibilities with pre-existing mechanical equipment, dried bead formats are ideally suited for agricultural and remediational applications.