Most available 3D biofabrication technologies rely on single-component deposition methods, such as inkjet, extrusion, or light-assisted printing. It is unlikely that any of these technologies used individually would be able to replicate the complexity and functionality of living tissues. Recently, new biofabrication approaches have emerged that integrate multiple manufacturing technologies into a single biofabrication platform. This has led to fabricated structures with improved functionality. In this review, we provide a comprehensive overview of recent advances in the integration of different manufacturing technologies with the aim to fabricate more functional tissue structures. We provide our vision on the future of additive manufacturin...
Regenerative medicine and tissue engineering have seen unprecedented growth in the past decade, driv...
3D bioprinting is an additive biomanufacturing technology having potential to fast-forward the trans...
The burgeoning field of additive manufacturing, or “3D printing”, centers on the idea of creating th...
Most available 3D biofabrication technologies rely on single-component deposition methods, such as i...
Most available 3D biofabrication technologies rely on single-component deposition methods, such as i...
© 2020 Elsevier Ltd Most available 3D biofabrication technologies rely on single-component depositio...
Additive manufacturing (AM), sometimes called three-dimensional (3D) printing, has attracted a lot o...
In biofabrication, researchers aim to produce three-dimensional (3D) constructs for the regeneration...
Recent advances in additive manufacturing (AM) techniques in terms of accuracy, reliability, the ran...
In recent years we have outrun our ability to fabricate structures from the amazing materials that w...
The introduction of additive manufacturing (AM), often referred to as three-dimensional (3D) printin...
Biofabrication exploits additive manufacturing techniques for creating 3D structures with a precise ...
The goal of scaffold-based tissue engineering is to create synthetic replacements for natural tissue...
When it comes to tissue engineering, 3D printing is a crucial technique for creating intricate const...
Regenerative medicine and tissue engineering have seen unprecedented growth in the past decade, driv...
3D bioprinting is an additive biomanufacturing technology having potential to fast-forward the trans...
The burgeoning field of additive manufacturing, or “3D printing”, centers on the idea of creating th...
Most available 3D biofabrication technologies rely on single-component deposition methods, such as i...
Most available 3D biofabrication technologies rely on single-component deposition methods, such as i...
© 2020 Elsevier Ltd Most available 3D biofabrication technologies rely on single-component depositio...
Additive manufacturing (AM), sometimes called three-dimensional (3D) printing, has attracted a lot o...
In biofabrication, researchers aim to produce three-dimensional (3D) constructs for the regeneration...
Recent advances in additive manufacturing (AM) techniques in terms of accuracy, reliability, the ran...
In recent years we have outrun our ability to fabricate structures from the amazing materials that w...
The introduction of additive manufacturing (AM), often referred to as three-dimensional (3D) printin...
Biofabrication exploits additive manufacturing techniques for creating 3D structures with a precise ...
The goal of scaffold-based tissue engineering is to create synthetic replacements for natural tissue...
When it comes to tissue engineering, 3D printing is a crucial technique for creating intricate const...
Regenerative medicine and tissue engineering have seen unprecedented growth in the past decade, driv...
3D bioprinting is an additive biomanufacturing technology having potential to fast-forward the trans...
The burgeoning field of additive manufacturing, or “3D printing”, centers on the idea of creating th...