Melt electrowriting of hydrophilic/hydrophobic multiblock copolymers for bone tissue regeneration.

Bone-healing complications can occur due to large bone defects or an insufficient bone regeneration capacity. Melt electrowriting (MEW) is a potential candidate for manufacturing synthetic scaffolds that may resolve bone-healing complications. MEW can exploit various biocompatible polymers with a wide range of tissue engineering applications.

Universal Strategy for Designing Shape Memory Hydrogels.

Smart polymeric biomaterials have been the focus of many recent biomedical studies, especially those with adaptability to defects and potential to be implanted in the human body. Herein we report a versatile and straightforward method to convert non-thermoresponsive hydrogels into thermoresponsive systems with shape memory ability. As a proof of concept, a thermoresponsive polyurethane mesh was embedded within a methacrylated chitosan (CHTMA), gelatin (GELMA), laminarin (LAMMA) or hyaluronic acid (HAMA) hydrogel network, which afforded hydrogel composites with shape memory ability.

Engineering bone-forming biohybrid sheets through the integration of melt electrowritten membranes and cartilaginous microspheroids.

Bone fractures are one of the most common traumatic large-organ injuries and although many fractures can heal on their own, 2-12% of fractures are slow healing or do not heal (non-unions). Autologous grafts are currently used for treatment of non-unions but are associated with limited healthy bone tissue. Tissue engineered cell-based products have promise for an alternative treatment method.

A Humanized In Vitro Model of Innervated Skin for Transdermal Analgesic Testing.

Sensory innervation of the skin is essential for its function, homeostasis, and wound healing mechanisms. Thus, to adequately model the cellular microenvironment and function of native skin, in vitro human skin equivalents (hSE) containing a sensory neuron population began to be researched. In this work, a fully human 3D platform of hSE innervated by induced pluripotent stem cell-derived nociceptor neurospheres (hNNs), mimicking the native mode of innervation, is established.

Assessing the response of human primary macrophages to defined fibrous architectures fabricated by melt electrowriting.

The dual role of macrophages in the healing process depends on macrophage ability to polarize into phenotypes that can propagate inflammation or exert anti-inflammatory and tissue-remodeling functions. Controlling scaffold geometry has been proposed as a strategy to influence macrophage behavior and favor the positive host response to implants. Here, we fabricated Polycaprolactone (PCL) scaffolds by Melt Electrowriting (MEW) to investigate the ability of scaffold architecture to modulate macrophage polarization.

Fabrication of a self-assembled honeycomb nanofibrous scaffold to guide endothelial morphogenesis.

Controlling angiogenesis within tissue engineered constructs remains a critical challenge, especially with regard to the guidance of pre-vascular network formation. Here, we aimed to regulate angiogenesis on a self-assembled honeycomb nanofibrous scaffold. Scaffolds with honeycombs patterns have several desirable properties for tissue engineering, including large surface area, high structural stability and good permeability.