In the last few years, clinical procedures undergone huge modifications. Among them,
mini-invasive surgery has modified the clinical practice and the quality of life of patients. Shape
Memory Polymers (SMPs), a class of stimuli-responsive materials, can be considered ideal
candidates for the design of devices for mini-invasive surgical procedures. Such a device can be
inserted in a packed in, temporary shape and later can expand at body temperature. A bone defect
could be filled by a SMP porous structure, that improves the tissue integration and healing.
In this work, two different processing techniques to obtain porous shape memory polymer scaffolds
from Calo MER™ and MM-4520, two SMPs, are presented. Porous structures were obtained by
micro-extrusion with different chemical foaming agents or with sodium chloride, or by solvent
casting/particulate leaching. The morphology, the thermo-mechanical and the shape recovery
properties of the SMP porous samples were investigated. Tridimensional porous structures showed
a well interconnected morphology, with a pore size in the range aimed for bone interaction
applications. The shape memory properties were not significantly affected by the transformation
processes: a good ability of recovering the original shape was verified. Therefore, the porous
structures, obtained from these SMP materials, appear adequate for an use as bone filler.
Harnessing reversible dry adhesion using shape memory polymer microparticles