Abstract
Additive manufacturing (AM), frequently cited as three-dimensional (3D) printing, is a relatively new manufacturing technique for biofabrication, also called 3D manufacture with biomaterials and cells. Recent advances in this field will facilitate further improvement of personalized healthcare solutions. In this regard, tailoring several healthcare products such as implants, prosthetics, and in vitro models, would have been extraordinarily arduous beyond these technologies. Three-dimensional-printed structures with a multiscale porosity are very interesting manufacturing processes in order to boost the capability of composite scaffolds to generate bone tissue. The use of biomimetic hydroxyapatite as the main active ingredient for bioinks is a helpful approach to obtain these advanced materials. Thus, 3D-printed biomimetic composite designs may produce supplementary biological and physical benefits. Three-dimensional bioprinting may turn to be a bright solution for regeneration of bone tissue as it enables a proper spatio-temporal organization of cells in scaffolds. Different types of bioprinting technologies and essential parameters which rule the applicability of bioinks are discussed in this review. Special focus is made on hydroxyapatite as an active ingredient for bioinks design. The goal of such bioinks is to reduce the constraints of commonly applied treatments by enhancing osteoinduction and osteoconduction, which seems to be exceptionally promising for bone regeneration.
Highlights
Received: 24 November 2021All along the processes of biomineralization, the organism possesses the ability to produce and deposit different types of minerals with the purpose of hardening or stiffening existing tissues
Electrostatic inkjet bioprinting is driven by the voltage given to a motor and a platen, provoking a bend on a platen that produces the bioink by extrusion
Recent literature on 3D printing of hydroxiapatite-based bioinks for various applications has been revised in this review
Summary
All along the processes of biomineralization, the organism possesses the ability to produce and deposit different types of minerals with the purpose of hardening or stiffening existing tissues. Biomaterials of synthetic origin composed of HA have been broadly researched as components of artificial bone grafts as well as surface coating agents These materials are bioactive and biocompatible by definition and display mechanical properties and a porous structure that enables their implantation into the human body [7]. The bioceramics which rapidly stimulate osteointegration and bone tissue generation are those that imitate the composition and structure of the bone mineral In this regard, it has been demonstrated that ceramic biomaterials produced from HA nanoparticles show an improved resorbability and enhanced bioactivity than ceramics of micrometre range size [11,12]. Bioprinting parameters including the effects of pressure, temperature, nozzle size of the bioprinter, bioink viscosity, the macrostructure of the resulting material (i.e., porosity) and crosslinking methods are issues of consideration for the production of substitutes of bone tissue [18,19]
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