Liver Tissue Engineering within Alginate Scaffolds: Effects of Cell-Seeding Density on Hepatocyte Viability, Morphology, and Function

Dvir-Ginzberg, Mona; Gamlieli-Bonshtein, Iris; Agbaria, Riad; Cohen, Smadar

doi:10.1089/107632703768247430

Cited by 228 publications

(151 citation statements)

References 30 publications

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“…In the present study, the viability of cells in the centre of both 2 and 5% w/v alginate hydrogel beads of 3-mm diameter was observed ( Fig. 1) It is proposed that the lack of mitotic activity is due in part to the use of a relatively low cell-seeding density [35], the encapsulation of dispersed cells rather than spheroids [36], the use of a non-liquefied core [37] and the use of high concentrations of alginate, which resulted in the fibroblasts being mechanically confined from each other by cross-linked chains of alginate. These results demonstrate that encapsulation in alginate effectively mitotically inhibits the fibroblasts without the need for treatment with Mitomycin C or gamma-irradiation, to allow for co-culturing of keratinocytes with the fibroblasts.…”

Section: Resultssupporting

confidence: 56%

An alginate hydrogel matrix for the localised delivery of a fibroblast/keratinocyte co‐culture

Hunt

Shelton

Grover

2009

Biotechnology Journal

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International audienceThere is significant interest in the development of tissue engineered skin analogues which replace both the dermal and the epidermal layer, without the use of animal or human derived products such as collagen or de-epidermalised dermis (DED). In this study, we proposed that alginate hydrogel could be used to encapsulate fibroblasts and that keratinocytes could be cultured on the surface to form a bilayered structure which could be used to deliver the co-culture to a wound bed, initially providing wound closure and eventually expediting the healing process. Encapsulation of fibroblasts in 5% alginate hydrogel effectively inhibited their proliferation, whilst maintaining cell viability allowing keratinocytes to grow uninhibited by fibroblast overgrowth to produce a stratified epidermal layer. It was shown that the alginate degradation process was not influenced by the presence of fibroblasts within the hydrogel and that lowering the alginate concentration to 2% w/v increased the rate of degradation. Cells released from the scaffold were able to secrete extra-cellular matrix (ECM) and thus should replace the degrading scaffold with normal ECM following application to the wound site. These findings demonstrate that alginate hydrogel may be an effective delivery vehicle and scaffold for the healing of full-thickness skin wounds

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Section: Resultssupporting

confidence: 56%

An alginate hydrogel matrix for the localised delivery of a fibroblast/keratinocyte co‐culture

Hunt

Shelton

Grover

2009

Biotechnology Journal

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“…Hepatocytes were seeded on three gNWF disks and cultured for 10 days in the bioreactor to determine non-destructive cell release at 20°C. To determine cell viability, cells were stained with fluorescein diacetate, which is essentially converted into fluorescein, a green fluorescent compound, by viable cells only [38]. Fig.…”

Section: Temperature-induced Cell Releasementioning

confidence: 99%

Development of thermoresponsive poly(propylene-g-N-isopropylacrylamide) non-woven 3D scaffold for smart cell culture using oxyfluorination-assisted graft polymerisation

Chetty

Vargha

Maity

et al. 2013

Colloids and Surfaces A: Physicochemical and Engineering Aspect

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Growing cells on 3D scaffolds is far superior to the conventional 2D monolayer culture method. In this study, a novel 3D thermoresponsive poly(propylene-g-Nisopropylacrylamide) (PP-g-PNIPAAm) non-woven fabric (gNWF) was developed for cell culture using oxyfluorination-assisted graft polymerisation (OAGP). New polar functional groups were detected on the oNWF, and PNIPAAm was confirmed in the gNWF by Attentuated Total-Reflectance Fourier transform infrared (ATR-FTIR) and scanning x-ray photoelectron spectroscopy (S-XPS). Scanning electron microscopy (SEM) revealed a rough surface morphology and confinement of the PNIPAAm graft layer to the surface of the fibres in the gNWF. The OAGP method did not affect the crystalline phase of bulk PP, however, twin-melting thermal peaks were detected for the oNWF and gNWF indicating crystal defects. Contact angle studies showed that the surface of the gNWF exhibited a thermoresponsive behaviour. Hepatocyte cells attached onto gNWF disks in a bioreactor at 37ºC and remained viable for 10 days in culture. Upon cooling the cell culture media to 20ºC, cells were spontaneously released as 3D multi-cellular constructs without requiring destructive enzymes. The development of 3D thermoresponsive scaffolds capable of non-invasive 3D cell culture could provide a more reliable in vitro model for cells.

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“…Previously, the active interaction between collagen and the embedded cells was assumed to enhance cellular functions (Wu et al 1996;Yamada et al 2001) and, furthermore, high cell density culture was highly suggested to enhance cell viability and hepatocellular functions such as albumin and urea secretion and detoxification (Dvir-Ginzberg et al 2003). Nevertheless, in this paper, the non-correlation between gel contraction and cell activity was unexpectedly concluded as a result of the fact that cell viability as well as liver-specific functions per viable cell were lower in the gel entrapment cultures at higher cell densities regardless of the more severe gel contraction observed.…”

Section: Discussionmentioning

confidence: 99%

“…Nevertheless, high cell density as well as high cellular functions were required for clinical use of BAL and in vitro model of drug screening platform. Dvir-Ginzberg et al (2003) adopted alginate scaffolds with high porosity and large pore sizes to improve mass transfer for sustaining high cell viability under high cell loading. In consideration of the adverse effect of gel contraction on cellular functions, we strongly recommend that gel contraction should be avoided due to its negative effect on mass transfer.…”

Section: Discussionmentioning

confidence: 99%

Interaction between hepatocytes and collagen gel in hollow fibers

2009

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Gel entrapment culture of primary mammalian cells within collagen gel is one important configuration for construction of bioartificial organ as well as in vitro model for predicting drug situation in vivo. Gel contraction in entrapment culture, resulting from cell-mediated reorganization of the extracellular matrix, was commonly used to estimate cell viability. However, the exact influence of gel contraction on cell activities has rarely been addressed. This paper investigated the gel contraction under varying culture conditions and its effect on the activities of rat hepatocyte entrapped in collagen gel within hollow fibers. The hepatocyte activities were reflected by cell viability together with liver-specific functions on urea secretion and cytochrome P450 2E1. Unexpectedly, no gel contraction occurred during gel entrapment culture of hepatocyte under a high collagen concentration, but hepatocytes still maintained cell viability and liver-specific functions at a similar level to the other cultures with normal gel contraction. It seems that cell activities are unassociated with gel contraction.Alternatively, the mass transfer resistance induced by the combined effect of collagen concentration, gel contraction and cell density could be a side effect to reduce cell activities. The findings with gel entrapment culture of hepatocytes would be also informative for the other cell culture targeting pathological studies and tissue engineering.

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Liver Tissue Engineering within Alginate Scaffolds: Effects of Cell-Seeding Density on Hepatocyte Viability, Morphology, and Function

Cited by 228 publications

References 30 publications

An alginate hydrogel matrix for the localised delivery of a fibroblast/keratinocyte co‐culture

An alginate hydrogel matrix for the localised delivery of a fibroblast/keratinocyte co‐culture

Development of thermoresponsive poly(propylene-g-N-isopropylacrylamide) non-woven 3D scaffold for smart cell culture using oxyfluorination-assisted graft polymerisation

Interaction between hepatocytes and collagen gel in hollow fibers

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