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

Breguet, Véronique; Gügerli, Raphael; Stockar, Urs von; Marison, I. W.

doi:10.1007/s10616-007-9045-8

Cited by 30 publications

(24 citation statements)

References 29 publications

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“…In this respect, semi-liquid cores appear to be the best compromise. 128 Cells-core/shell capsules are an interesting alternative, but several questions pertaining to mechanical resistance (related to strength of the cell aggregates), the consequences of cell growth and death on the integrity of the immunoisolation barrier, and finally, long-term stability and performance need to be addressed.…”

Section: Resultsmentioning

confidence: 99%

“…19 It has been reported that the hydrogel network can reduce cell growth and protein production by exerting stress not present in liquid or semi-liquid capsules. [127][128][129] Moreover, diffusion of gases and nutrients is higher in liquid than in gel. The objectives of encapsulating mammalian cells in liquid-core microcapsules (Figure 2b) have been pursued with a wide range of techniques, from interfacial polymerization, interfacial precipitation to PEC membrane and sacrificial core methods (Table 5).…”

Section: Liquid-core/shell Microcapsulesmentioning

confidence: 99%

“…Although beneficial for cell growth, core liquifaction weakens mechanical resistance of the capsules. 128 Transient alginate scaffold beads have been promoted for the assembly of CS/pDADMAC PE shells. These co-called ''CellMAC'' capsules, after dissolution of the alginate bead scaffold, proved to display excellent mechanical properties and cell viability.…”

Section: Capsule Wall Formation By Pe Depositionmentioning

confidence: 99%

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Progress technology in microencapsulation methods for cell therapy

Rabanel

Banquy

Zouaoui

et al. 2009

Biotechnology Progress

120

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Cell encapsulation in microcapsules allows the in situ delivery of secreted proteins to treat different pathological conditions. Spherical microcapsules offer optimal surface-to-volume ratio for protein and nutrient diffusion, and thus, cell viability. This technology permits cell survival along with protein secretion activity upon appropriate host stimuli without the deleterious effects of immunosuppressant drugs. Microcapsules can be classified in 3 categories: matrix-core/shell microcapsules, liquid-core/shell microcapsules, and cells-core/shell microcapsules (or conformal coating). Many preparation techniques using natural or synthetic polymers as well as inorganic compounds have been reported. Matrix-core/shell microcapsules in which cells are hydrogel-embedded, exemplified by alginates capsule, is by far the most studied method. Numerous refinement of the technique have been proposed over the years such as better material characterization and purification, improvements in microbead generation methods, and new microbeads coating techniques. Other approaches, based on liquid-core capsules showed improved protein production and increased cell survival. But aside those more traditional techniques, new techniques are emerging in response to shortcomings of existing methods. More recently, direct cell aggregate coating have been proposed to minimize membrane thickness and implants size. Microcapsule performances are largely dictated by the physicochemical properties of the materials and the preparation techniques employed. Despite numerous promising pre-clinical results, at the present time each methods proposed need further improvements before reaching the clinical phase.

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Section: Resultsmentioning

confidence: 99%

Section: Liquid-core/shell Microcapsulesmentioning

confidence: 99%

Section: Capsule Wall Formation By Pe Depositionmentioning

confidence: 99%

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Progress technology in microencapsulation methods for cell therapy

Rabanel

Banquy

Zouaoui

et al. 2009

Biotechnology Progress

120

View full text Add to dashboard Cite

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“…This could be attributed to the formation of a smooth structure within the microcapsule; free volume for the bacteria needed to proliferate inside the microcapsule was insufficient. [70] …”

Section: Morphological Analysismentioning

confidence: 99%

Whey Protein-Pullulan (WP/Pullulan) Polymer Blend for Preservation of Viability ofLactobacillus acidophilus

Çabuk

Harsa

2015

Drying Technology

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In this study, whey protein isolate-pullulan (WP/pullulan) microspheres were developed to entrap the probiotic Lactobacillus acidophilus NRRL-B 4495 by spray-drying technique. Microcapsules were analyzed for physicochemical characteristics including morphology, particle size, moisture content, water activity, dissolution time, and color properties. Results revealed that microcapsules were spherical in shape and obtained particle sizes between 5 and 160 lm, with an average size of around 50 lm. Blending pullulan with WP provided enhanced survival of probiotic bacteria during spray drying with a final viable cell number of 8.81 log CFU/g of microcapsule. Encapsulated probiotics were also found to have significantly (p 0.05) higher survived cell numbers compared to free probiotics under detrimental gastrointestinal conditions. Moreover, dissolution analysis suggested that protein-polysaccharide powdered microcapsules showed pH-sensitive dissolution properties in simulated gastric juice and simulated intestinal juice.

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“…On the other hand immobilized cultures do not require sophisticated equipment to retain the cells within the vessel. A simple mesh is sufficient to extract the spent media as represented in Figure 1B [5]. Mammalian cell cultures are highly complex and may vary from one culture to another.…”

Section: Introductionmentioning

confidence: 99%

The Application of Dielectric Spectroscopy and Biocalorimetry for the Monitoring of Biomass in Immobilized Mammalian Cell Cultures

2015

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Abstract:The purpose of this study was to introduce dielectric spectroscopy and biocalorimetry as monitoring methods to follow immobilised Chinese Hamster Ovary (CHO) cell culture development. The theory behind both monitoring techniques is explained and perfusion cultures are performed in a Reaction Calorimeter (eRC1 from Mettler Toledo) as an application example. The findings of this work show that dielectric spectroscopy gives highly reliable information upon the viable cell density throughout the entire culture. On the other hand, the RC1 could only provide accurate data from day 5, when the cell density exceeded 4 × 10 , a viable cell density commonly achieved in fed-batch and the early stages of a perfusion culture. This work suggests that biocalorimetry should be possible to implement at industrial scale to monitor CHO cell cultures.

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

Cited by 30 publications

References 29 publications

Progress technology in microencapsulation methods for cell therapy

Progress technology in microencapsulation methods for cell therapy

Whey Protein-Pullulan (WP/Pullulan) Polymer Blend for Preservation of Viability ofLactobacillus acidophilus

The Application of Dielectric Spectroscopy and Biocalorimetry for the Monitoring of Biomass in Immobilized Mammalian Cell Cultures

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