Taking into account the current trend for environmentally friendly solutions, paper coated with a biopolymer presents an interesting field for future packaging applications. This study covers the application of the biopolymer poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) on a paper substrate via extrusion coating. The intention of this study is to analyse the effect of a plasticiser on the processability (melting point, film thickness) and the final properties (crystallinity, elongation at break) of PHBV. Up to 15 wt.% of the plasticisers triethyl citrate (TEC) and polyethylene glycol (PEG) were used as additive. The processing (including melt flow rate) as well as the structural properties (melting and crystallisation temperature, surface structure by atomic force microscopy (AFM), polarisation microscopy, scanning electron microscopy (SEM)), mechanical properties (elongation at break, tensile strength, elastic modulus, adhesion), and barrier properties (grease) of these blends and their coating behaviour (thickness on paper), were tested at different extrusion temperatures. The melting temperature (Tm) of PHBV was reduced by the plasticisers (from 172 °C to 164 resp. 169 °C with 15 wt.% TEC resp. PEG). The minimal achieved PHBV film thickness on paper was 30 µm owing to its low melt strength. The elastic modulus decreased with both plasticisers (from 3000 N/mm2 to 1200 resp. 1600 N/mm2 with 15 wt.% TEC resp. PEG). At 15 wt.% TEC, the elongation at break increased to 2.4 length-% (pure PHBV films had 0.9 length-%). The grease barrier (staining) was low owing to cracks in the PHBV layers. The extrusion temperature correlated with the grease barrier, mechanical properties, and bond strength. The bond strength was higher for films extruded with a temperature profile for constant melt flow rate at different plasticiser concentrations. The bond strength was max. 1.2 N/15 mm. Grease staining occurs because of cracks induced by the low elongation at break and high brittleness. Extrusion coating of the used specific PHBV on paper is possible. In further studies, the minimum possible PHBV film thickness needs to be reduced to be cost-effective. The flexibility needs to be increased to avoid cracks, which cause migration and staining.
Metallized films consisting of thin, vacuum-deposited inorganic layers are used for a wide range of packaging applications for foods, pharmaceuticals and other technical purposes. They are made as laminates and consist of a polymeric film (substrate), an inorganic layer, mostly aluminum (Al), and a top layer, laminated to the inorganic layer using a suitable adhesive. One major quality indicator in such flexible packaging materials is the adhesion strength between the inorganic layer and the substrate. In order to measure the adhesion strength of thin Al layers deposited on a substrate, the following procedure is often used: Ethylene acrylic acid (EAA)-films are thermally sealed to the Al layers. In a subsequent peel test, the EAA-film is peeled-off at 180 • peel angle, delaminating the Al layer from the substrate. This method shows weaknesses in cases of high bond strength: The sealed EAA-film is elongated or even torn during the measurements, whereby it is difficult to obtain reproducible and repeatable results. In this study two alternative approaches have been tested to overcome the weaknesses of EAA-peel test. One of them is to use thermally sealable polymeric films, such as amorphous poly(ethylene terephthalate) and amorphous polyamide (both having a high mechanical strength), instead of the EAA film. Although the adhesion forces might have been weakened during the heat lamination of these selected films onto the Al surface, a quantitative comparison between the three different types of metallized films (with low, medium and high adhesion strength) is found to be promising by this approach. The other approach is to perform the peel tests with the laminates of the metallized films. The laminates are produced by laminating a low density polyethylene film (PE-LD) on top of the metallized film using an adhesive via a bench lamination process. The laminated PE-LD film in this case replaces the EAA-film. In this approach, the laminate structure is similar to the final product in the end-use. The metal adhesion strength is found to be in good agreement with the strength measured for similar structures produced at pilot scale.
Novel approaches in regenerative medicine and tissue engineering are highly promoted by human induced pluripotent stem cells. Typical workflows include the expansion, differentiation and/or cryopreservation of these cells. Often, the differentiation, cytotoxicity tests or disease modelling rely on multicellular aggregates. Here, we present the novel bag-based system "Labbag®" to address workflows required for these applications. As a unique feature, the Labbag® provides a chemical spot pattern to allow the formation of several hundreds of hanging droplets within a few seconds with standard laboratory equipment. In this study, we describe the general concept of the Labbag® and show aggregate formation of stem cells as first stem cell workflow successfully transferred.
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