Hydrogels are one of the most widespread biomaterials used in tissue engineering. However, they possess weak mechanical properties and are often unstable in load‐bearing applications in vivo. A novel class of flexible Ti–6Al–4V titanium alloy lattices manufactured using laser powder bed fusion (L‐PBF) serves as a tunable reinforcement for hydrogels, providing them with additional mechanical stability and flexibility, while ensuring biocompatibility. A study on the design parameters of the structural elements of the lattices is performed to evaluate their influence on the mechanical properties of the structure. Mechanical testing of Ti–6Al–4V lattices shows a compressive modulus ranging from 38.9 to 895.5 kPa in the flexible direction. In th...
Mechanical and architectural features play an important role in designing biomedical devices. The us...
Published ArticleTopology optimization approach was used for the design of Ti6Al4V ELI lattice struc...
Porous Lattice Structure (PLS) scaffolds have shown potential applications in the biomedical domain....
Hydrogels are one of the most widespread biomaterials used in tissue engi- neering. However, they p...
The development of porous metals to alleviate the effects of stress shielding in bone will help impr...
This work aimed to study one of the most important challenges in orthopaedic implantations, known as...
This work aimed to study one of the most important challenges in orthopaedic implantations, known as...
Intervertebral cages made of Ti6Al4V alloy show excellent osteoconductivity, but also higher stiffne...
With the rapid advancements in technology, there has been an increased usage of Additive Manufacturi...
The call for orthopedic implants is a growing concern with an ever-rising aging population. Current ...
The performance of many metal biomedical implants – such as fusion cages for spines – is inherently ...
Integrating porous networks in load-bearing implants is essential in order to improve mechanical com...
Laser powder bed fusion (L-PBF) techniques have been increasingly adopted for the production of high...
The development of medical implants is an ongoing process pursued by many studies in the biomedical ...
Lattice structure topology is a rapidly growing area of research facilitated by developments in addi...
Mechanical and architectural features play an important role in designing biomedical devices. The us...
Published ArticleTopology optimization approach was used for the design of Ti6Al4V ELI lattice struc...
Porous Lattice Structure (PLS) scaffolds have shown potential applications in the biomedical domain....
Hydrogels are one of the most widespread biomaterials used in tissue engi- neering. However, they p...
The development of porous metals to alleviate the effects of stress shielding in bone will help impr...
This work aimed to study one of the most important challenges in orthopaedic implantations, known as...
This work aimed to study one of the most important challenges in orthopaedic implantations, known as...
Intervertebral cages made of Ti6Al4V alloy show excellent osteoconductivity, but also higher stiffne...
With the rapid advancements in technology, there has been an increased usage of Additive Manufacturi...
The call for orthopedic implants is a growing concern with an ever-rising aging population. Current ...
The performance of many metal biomedical implants – such as fusion cages for spines – is inherently ...
Integrating porous networks in load-bearing implants is essential in order to improve mechanical com...
Laser powder bed fusion (L-PBF) techniques have been increasingly adopted for the production of high...
The development of medical implants is an ongoing process pursued by many studies in the biomedical ...
Lattice structure topology is a rapidly growing area of research facilitated by developments in addi...
Mechanical and architectural features play an important role in designing biomedical devices. The us...
Published ArticleTopology optimization approach was used for the design of Ti6Al4V ELI lattice struc...
Porous Lattice Structure (PLS) scaffolds have shown potential applications in the biomedical domain....