Effect of miscibility on mechanical and thermal properties of poly(lactic acid)/ polycaprolactone blends

Abstract: In this work, binary blends based on poly(lactic acid)-PLA and poly(caprolactone)-PCL were prepared by melt mixing in a twin screw co-rotating extruder in order to increase the low intrinsic elongation at break of PLA for packaging applications. Although PLA and PCL show low miscibility, presence of PCL leads to a remarkable increase in ductile properties of PLA.Different mechanical properties were evaluated in terms of PCL content up to 30 weight % PCL. Additionally to tensile and flexural properties, the Poi… Show more

“…Poly(ε-caprolactone) (PCL) has also been reported to increase the elongation-at-break and thermal stability for PLA in a blend, accompanied by a decrease in the tensile strength and modulus compared to neat PLA due to the lower values of these properties in PCL [46,47]. Hence the interfaces between two polymers are improved.…”

Poly(lactic acid) blends in biomedical applications

“…Poly(ε-caprolactone) (PCL) has also been reported to increase the elongation-at-break and thermal stability for PLA in a blend, accompanied by a decrease in the tensile strength and modulus compared to neat PLA due to the lower values of these properties in PCL [46,47]. Hence the interfaces between two polymers are improved.…”

Poly(lactic acid) blends in biomedical applications

“…The percentage crystallinity of PLA and plasticized formulations was calculated with the following equation: where Δ H m and Δ H c represent the experimental melt and cold crystallization enthalpies, respectively, and w is the weight fraction of PLA. Δ H m 0 is the melt enthalpy for a theoretical fully crystalline PLA structure, and was assumed to be 93 J g −1 as reported in the literature …”

“…Its biodegradability in natural media makes it the ideal choice for a wide range of disposable products that can undergo disintegration by hydrolysis and enzymatic degradation in controlled conditions (moisture, temperature, bacterial growth, etc.) . Moreover, PLA is characterized by high biocompatibility and a good balance of mechanical properties, thus widening its uses in the medical sector, such as in resorbable interference screws and prostheses subjected to moderate mechanical stresses .…”

The effect of maleinized linseed oil as biobased plasticizer in poly(lactic acid)‐based formulations

“…Accordingly, many scientists have focused on finding new highly compatible and biodegradable biomaterials, which can be substituted to damaged tissues through activation of curative mechanisms. [11][12][13] On the other hand, with the advent of nanotechnology, the use of nanomaterials in the polymer blend formulations has been accepted as a versatile approach for producing robust materials. Biopolymers are widely used in synthetic scaffolds because they provide a wide range of biomechanical properties, good formability, and easy availability.…”

Disclosing the role of surface and bulk erosion on the viscoelastic behavior of biodegradable poly(ε‐caprolactone)/poly(lactic acid)/hydroxyapatite nanocomposites