2. Experimental2.1. Materials and p

2. Experimental
2.1. Materials and preparation
Multi layer films were produced using as substrate a commercial
film under the trade name Bio-FlexR F 2110 (prev. Bio-FlexR 467F)
provided by FKuR Kunststoff GmbH, Willich, Germany, of thickness
58 mm. The BIO-FLEX® trade name indicates blends of co-polyester
and PLA CAS 9051e89e2, this film is hereafter referred to as PLA.
The aqueous coating solution used for testing, and hereafter
referred to as Whey, mainly comprises whey protein isolate (WPI)
BiPro (10 wt% in aqueous solution) of Davisco Foods International
(Le Sueur, MN, USA) (dry protein pureness 97.4%; N 6.38). Sorbitol,
supplied by Merck KG (Darmstadt, Germany), was used as plasticizer
at 100 wt% based on protein content in the aqueous solution
and mixed with the denatured whey protein solution as reported
elsewhere [13,40,41].
The layer of whey protein was coated onto the substrate film
using an A4-A3 sample size control coater of Erichson GmbH & Co.
KG, Hemer, Germany. The Whey dry coating thickness was 10 mm
leading to a total laminate structure (PLA/Whey) thickness of
68 mm.
Thefilms were dried at 23C and 50% RH until the samples reached
the equilibrium moisture content at the given temperature and humidity
but at least for one week. These samples were used for measurements
of permeability, mechanical properties and degradation.
2.2. Methods
Oxygen permeability of the substrate and the coated PLA/Whey
films were measured according to DIN 53380-3 (DIN, 1998) at 23 C
and 50% RH using an Ox-Tran 2/20 (Mocon Inc., Minneapolis, MN,
USA). The coated side of the films was exposed to flowing oxygen
gas and the other side to flowing nitrogen gas. Resulting oxygen
permeability of multilayer films was deduced in terms of cm3
(STP)$m2 d1 bar1 and used for further calculations regarding
permeability of the single whey protein layer. A Whey-coated
polymer film can be considered as a 2-layer-structure, comparable
to a laminated material [14,26]. The following equations (1) and
(2) can be used:
d
P ¼ d1
P1
þ
d2
P2
(1)
1
Qtot
¼ Xdi
Pi
¼ 1
Q1
þ
1
Q2
þ
1
Q3
þ … (2)
where d represents the thickness of each layer, i, (d ¼ S di) and P
is the oxygen permeability of each layer. Subscript 1 stands for
the polymer film and subscript 2 for the Whey layer coating on
the surface.
Oxygen permeability values of whey-based coatings are converted
to a thickness of 100 mm (Q100) in order to allow direct
comparison of different materials independently of the coating
thickness according to the following equation (3).
Q100 ¼ Q  ðd=100Þ (3)
Film thicknesses were measured with the instrument Mahr
Millimar C1216 of Mahr GmbH (Gottingen, Germany) after oxygen €
transmission tests. The thickness of the whey layer coating was
calculated by subtracting the base for PLA film. Five random positions
on the film were measured and averaged.
Samples of PLA films and PLA/Whey films were stamp cut in dog
bone shaped specimen: 11.5 cm length, 2.5 cm wide; 4.0 cm neck
length, 0.6 cm neck wide and used for tensile tests with an Instron
4302 tensile machine (Instron, Norwood, MA, USA), 1 kN cell Load,
running at 10 mm/min.
Scanning electron microscopy (SEM) was a JEOL JSM-5600LV
(Tokyo, Japan), samples were gold sputtered before the analysis
with an Edwards Sputter Coater (Edwards Ltd., Crawley, England).
Film samples with PLA and Whey were analysed for total
organic carbon (TOC) content by a modified method of EN13137
(coulometric). The carbon dioxide released by the combustion in
152 P. Cinelli et al. / Polymer Degradation and Stability 108 (2014) 151e157
oxygen containing gas flow, free of carbon dioxide at 900e1500 C
is measured by coulometry and indicates the TOC directly. Usually
silicate in the soil does not burn, which prevents the measurement
of TOC in the compost soil with the applied method. Therefore
water soluble fractions of carbon were determined photometrically
(Dr. Lange Test-Kit) in compost soil samples. Nitrogen is reported as
total Kjieldahl nitrogen.