3.2. Textural and rheological prope

3.2. Textural and rheological properties
When compared to plain chocolates, the addition of different types
of red raspberry leaf extract significantly (pb0.05) affected the instrumental
hardness and work of compression (Table 1), and lowered both
parameters in all types of chocolates (milk, semisweet, dark). Insignificant
differences (p>0.05) were observed only between hardness of plain dark
chocolate and dark chocolate containing 3% of concentrated extract. Plain
semisweet chocolate was the hardest, followed by plain dark chocolate,
and this ranking corresponds to the values obtained forwork of compression
that was required to penetrate/break the chocolate bars. Comparing
the hardness of chocolates enriched with different raspberry leaf extract
additions, it can be observed that different type of additions differently
affect the hardness of chocolates. Compared to plain chocolates, the addition
of 3% of concentrated extract and freeze dried extract significantly
(pb0.05) reduced the hardness of milk chocolate, 1% of concentrated
extract significantly reduced the hardness of semisweet chocolate, while
among dark chocolates, the lowest hardness was recorded for chocolate
containing freeze dried extract. In semisweet and dark chocolates, the addition
of 3% of concentrated extract resulted in increased hardness when
compared to other types of additions, which is in accordancewith the results
of rheological measurements. As can be seen in Table 1, both plastic
viscosity and shear stress are the highest in semisweet chocolate enriched
with 3% of concentrated extract. Even though the rheological parameters
could not have been measured in milk chocolate (most probably due to
poor tempering and presence of moisture which facilitated thickening
and preventing propermelting for viscosity readings) and dark chocolate
containing 3% of concentrated extract, it is obvious that compared to plain
chocolates the plastic viscosity is increasing upon the addition of different
red raspberry leaf extract forms (Table 1). This is not surprising, since
water has a severe thickening effect upon chocolate. In the presence of
water on the surface of the sugar particles, they start sticking together
and impeding the flow. According to Beckett (2008), approximately for
every 0.3% of moisture left in the chocolate mass (above a level of 1%) a
further 1% of fat must be added to compensate and restore the viscosity
to what it should be. Regression analysis showed that Casson plastic viscosity
and yield stress for the experimental chocolates are not closely related.
The regression model for these two parameters is as follows: Yield
stress=0.2031×Casson plastic viscosity+0.3623, with a regression
coefficient R2=0.521. The poor relationship may be attributed to the
differences between the samples, as can be seen in the relation of shear
rate versus shear stress performed at 40 °C for the experimental chocolates
displayed in Figs. 1 and 2. As can be seen in Figs. 1 and 2, plain
chocolates and the ones added with freeze-dried and 1% of concentrated
extracts exhibit similar relationship of shear rate vs. shear stress, as
opposed to chocolates added with 3% of concentrated extract. For both
semisweet (Fig. 1a, b) and dark (Fig. 2a, b) chocolates the addition of
3% of concentrated extract markedly altered the relationship between
shear rate and shear stress, which resulted with the highest Casson plastic
viscosity and yield stress for semisweet chocolate. The presence of
water in the corresponding dark chocolate caused aggregation and clothing
of dark chocolate containing 3% of raspberry leaf extract (similarly
as for milk chocolates), which disabled the viscosity readings for that
samples.
Smaller particle sizes in chocolate are known to improve sensory
properties (Ziegler, Mongia, & Hollender, 2001), but plastic viscosity
and yield stress increase due to increased surface area of particles in contact
with cocoa butter (Mongia & Ziegler, 2000). Therefore the yield
value usually correlates with the measured specific surface area. This is
however, not the case with the Casson plastic viscosity, where at very
large particle sizes the plastic viscosity can increase again, due to increasing
amounts of bound fat or how the solid particles pack themselves
together (Beckett, 2008). The raspberry leaf extract-enriched
experimental chocolates produced in our study showed no correlation
between the surfaceweightedmean and shear stress or plastic viscosity
(Table 1). Namely, chocolates with the lowest surface weighted mean
exhibited the highest plastic viscosity, which might be due to the presence
of other ingredients in the concentrated raspberry leaf extract. Increasing
solid concentration results in higher viscosity as shown by
Servais, Jones, and Roberts (2002). High solid content, interactions of
the suspended particles and their interfacial properties affect rheological
properties of chocolate (Bouzas & Brown, 1995). Since this medicinal
plant conta