Poly ether-ether-ketone (PEEK) is a polymer with better lignin biocompatibility than other
polymers. It is good for biomedical engineering applications. This research summarises the …

This study explores an innovative energy harvesting technique for biomedical implants in
alignment with the United Nations Sustainable Development Goals, focusing on good health …

The self-healing and biocompatibility of polymer composites for biomedicine have made
them a preferred approach for small-scale tissue engineering elements. By moving from …

The major drawback associated with PEEK implants is their biologically inert surface, which
caused unsatisfactory cellular response and poor adhesion between the implants and …

Abstract Poly-Ether-Ketone (PEEK) is a bioactive material capable of replacing traditional
metal and ceramic components in biomedical applications but still lacks some strength and …

Artificial bone implant materials need porosity for nutrient distribution, moderate pore size to
provide cell cultures and bone-like mechanical properties. The homogenisation of …

The addition of biomaterials such as Calcium Hydroxyapatite (cHAp) and incorporation of
porosity into poly-ether-ether-ketone (PEEK) are effective ways to improve bone-implant …

This review focuses on 3D printing of calcium hydroxyapatite (cHAp) as a composite on poly-
ether-ether-ketone (PEEK) scaffolds and related structures. The combination is made of …

Tissue engineering uses some engineering strategies for the reconstruction and repair of
the compromised tissues, among which the use of biomaterials as an alternative to …

Abstract 3D-printing is an efficient method of designing customised structures and producing
synthetic bone grafts appropriate for bone implants. This research aimed to manufacture a …