In recent years, new bio-based mate

In recent years, new bio-based materials for food packaging
have been designed in order to replace their non-degradable
counterparts, which are contemporaneously used (De Azeredo,
2009). It is well-known that high production costs of biodegrad-
able materials are a stumbling block, being an important disad-
vantage against synthetic ones. However, eco-friendly materials
development is justified since they guarantee environmental
preservation. This implies to protect non-renewable sources as well
as to avoid pollution problems related to the final disposition of
non-degradable materials (Davis & Song, 2006). Due to its avail-
ability, biodegradability, and low cost, starch is one of the most
natural polymers studied for packaging applications. Thermoplastic
starch (TPS) is obtained through granular disruption byshear forces
applied at high temperature in presence of a plasticizer (Corradini,
Carvalho, Curvelo, Agnelli, & Mattoso, 2007). Unfortunately, TPS
films have two main disadvantages in comparison to synthetic
polymers: moisture absorption susceptibility and poor mechanical
performance. One approach to overcome these drawbacks is the
reinforcement of TPS matrix adding natural organic or mineral
fillers. Among mineral fillers, talc is considered as a good candidate
in order to reinforce different kind of matrixes (Castillo, Barbosa, &
Capiati, 2012; Castillo et al., 2013). Talc is a phyllosilicate with a
layered structure which consists of octahedral brucite [Mg(OH)2]
sheets sandwiched between two tetrahedral silica [Si2O5] sheets.
Talc structure is composed of two kinds of surfaces: a weakly en-
ergetic “basal surface” with basic and hydrophobic SieOeSi groups
and a more energetic “edge surface” with acid and hydrophilic Sie
OH groups and residual magnesium cations (Comard et al., 2004).
Thus, both layered structure and the nanometric size thickness
make talc particles suitable to be intercalated by polymer chains
during composite processing (Castillo et al., 2013).