Porosity affects performance of scaffolds for bone tissue engineering both in vitro and in
vivo. Macropores (ie, pores with a diameter> 100 μm) are essential for cellular infiltration; …

Tissue engineering is a fascinating field that combines biology, engineering, and medicine
to create artificial tissues and organs. It involves using living cells, biomaterials, and …

Lightweight, strong, and energy-absorbing materials are highly sought after in practical
engineering applications. To this end, interpenetrating phase composites (IPC) stand as a …

The emergence of nanosheet materials like graphene and phosphorene, which are created
by breaking the interlayer van der Waals force, has revolutionized multiple fields. Layered …

Pickering emulsions and foams as well as capillary suspensions are becoming increasingly
more popular as inks for 3D printing. However, a lack of understanding of the bulk …

Customizing bone scaffolds to mimic the hierarchically porous structure of natural bone
presents a promising strategy for treating critical bone defects. Although low-cost direct ink …

Processing-structure-property relationships of 3D-printed multi-scale porous ceramics were
investigated. Direct ink writing (DIW) of oil-templated colloidal pastes produced …

Advances in additive manufacturing are leading to the emergence of new printable
applications, including sensors for healthcare monitoring and bioengineering scaffolds …

Despite advancements in medical care, the management of bone injuries remains one of the
most significant challenges in the fields of medicine and sports medicine globally. Bone …

Abstract 3D‐printed bioceramic scaffolds offer great potential for bone tissue engineering
(BTE) but their inherent brittleness and reduced mechanical properties at high porosities can …