scholarly journals 3D printed bone-like biopolymer composites inspired by nacre

2021 ◽  
Author(s):  
◽  
Mima Kurian

<p>Bone tissue engineering and synthetic biomineralization are two widely researched areas, the principles of which have been combined from time to time in efforts to develop replacement materials for natural bone grafts. Nacre has been studied as a prospective bone graft material owing to its mechanical strength being comparable to that of natural bone. The extraordinary mechanical strength of nacre is attributed to its nanostructure. The McGrath research group developed a synthetic biomineralization method, herein called the McGrath method, that can be used to effectively replicate the elements of nacre’s nanostructure in 2D biopolymer systems in laboratory conditions. Here, the applicability of the McGrath method in translating the calcium carbonate-based mineralization achieved in 2D films onto 3D printed chitosan hydrogel-based scaffolds is investigated. Thereby, enabling the fabrication of 3D chitosan-calcium carbonate composites with properties sought in the context of prospective load-bearing bone grafts.  In this work, considering the importance of interconnected porosity in an in vivo environment, nozzle extrusion-based 3D printing was employed to develop 3D structures with interconnected macropores, essentially imitating the porous structure of bone. The applicability of chitosan hydrogels as the printing ink in a custom-designed 3D printer was evaluated and quantified through rheological studies. The printing parameters and an appropriate experimental protocol were devised to fabricate stable 3D chitosan hydrogel-based scaffolds featuring physically crosslinked-layered structure with interconnected macropores. The effect of various drying techniques on retaining this porous structure in dried scaffolds and their swelling behaviour when soaked in a physiologically relevant solvent were explored using various techniques including cryo-scanning electron microscopy.  The strategies required to mineralize the as-fabricated 3D chitosan hydrogel-based scaffolds via the McGrath method, such that the mineralization achieved within the 3D scaffolds is similar to that obtained within 2D films, were elucidated. This included the use of polyacrylic acid (PAA), a crystal growth modifier. PAA has previously been shown to be important in achieving a pancake-like calcium carbonate formation, comprised of laterally growing nanoparticle aggregates which form in association with the organic matrix, in 2D films; such structures are observed in the early stages of nacre formation. By modulating the period of exposure of the 3D scaffolds to the mineralization solutions and the concentrations of these solutions, it was found that 3D composites with up to 40% calcium carbonate content and varying crystal morphology could be fabricated using this mineralization method. Importantly, it was observed that the calcium carbonate crystallites were intricately associated with the organic hydrogel matrix. This is another essential element observed in biomineral systems. Various techniques such as scanning electron microscopy (SEM), thermogravimetric analysis (TGA), energy dispersive spectroscopy (EDS) and X-ray diffraction (XRD) were employed for structural and compositional characterisation of the final composites.  The prospect of fabricating 3D chitosan-calcium carbonate composites via a single-step method using chitosan hydrogel preloaded with calcium carbonate crystallites as the printing ink in our custom-designed 3D printer was also investigated. This method was studied as a faster and less labour-intensive alternative to developing composites via the two-step method devised in this research whereby 3D hydrogel-based scaffolds are printed first and then mineralized via the McGrath method. The advantages and disadvantages of the two fabrication techniques are compared. The two-step fabrication method was found to be superior in terms of the properties explored and desired in the composite.  The behaviour of the chitosan hydrogel-based scaffolds and composites fabricated using the McGrath method, under different stress and strain regimes were also investigated. Mechanical tests performed on air-dried chitosan hydrogel-based scaffolds and composites showed that the compressive modulus, strength and indentation hardness values obtained were within the same order of magnitude as that of trabecular bone. Data from uniaxial compression tests showed that the yield, ultimate strength and compressive modulus of the 3D scaffolds vary with the total mineral content, morphology and size of the resultant crystallites in the composite. Composites with very low mineral content (~7% CaCO₃ content) showed the best mechanical properties under uniaxial compressive stress (approximately 0.37 GPa compressive modulus, 26 MPa yield strength, and 31 MPa ultimate strength). Nanoindentation tests showed that the nanoscale hardness and indentation modulus increased upon mineralization of the scaffolds but did not vary significantly as a function of the extent of mineralization. Dynamic mechanical analysis showed that the scaffolds (both mineralized and non-mineralized) can effectively dissipate stress without complete fracture when subjected to dynamic compressions within physiologically relevant loading frequencies (1 - 15 Hz) irrespective of the mineral content. The individual responses vary with loading frequency.  Having ascertained the structural and mechanical attributes of the fabricated materials, their capacity to enable osteoblast cell attachment and proliferation was explored. Alamar Blue assay and confocal microscopy performed at various time points for samples exposed to in vitro cultured osteoblasts showed that chitosan hydrogel-based scaffolds and composites are biologically non-toxic and facilitate cell adhesion and proliferation. Furthermore, when osteoblasts were incubated with composites with low CaCO₃ content, the number of cells increased significantly within 14 days.  The results of this research confirm that 3D printed chitosan hydrogel-based composites fabricated using the McGrath mineralization method featuring various structural and compositional imitations of bone and nacre shows considerable potential as future bone grafts materials.</p>

2021 ◽  
Author(s):  
◽  
Mima Kurian

<p>Bone tissue engineering and synthetic biomineralization are two widely researched areas, the principles of which have been combined from time to time in efforts to develop replacement materials for natural bone grafts. Nacre has been studied as a prospective bone graft material owing to its mechanical strength being comparable to that of natural bone. The extraordinary mechanical strength of nacre is attributed to its nanostructure. The McGrath research group developed a synthetic biomineralization method, herein called the McGrath method, that can be used to effectively replicate the elements of nacre’s nanostructure in 2D biopolymer systems in laboratory conditions. Here, the applicability of the McGrath method in translating the calcium carbonate-based mineralization achieved in 2D films onto 3D printed chitosan hydrogel-based scaffolds is investigated. Thereby, enabling the fabrication of 3D chitosan-calcium carbonate composites with properties sought in the context of prospective load-bearing bone grafts.  In this work, considering the importance of interconnected porosity in an in vivo environment, nozzle extrusion-based 3D printing was employed to develop 3D structures with interconnected macropores, essentially imitating the porous structure of bone. The applicability of chitosan hydrogels as the printing ink in a custom-designed 3D printer was evaluated and quantified through rheological studies. The printing parameters and an appropriate experimental protocol were devised to fabricate stable 3D chitosan hydrogel-based scaffolds featuring physically crosslinked-layered structure with interconnected macropores. The effect of various drying techniques on retaining this porous structure in dried scaffolds and their swelling behaviour when soaked in a physiologically relevant solvent were explored using various techniques including cryo-scanning electron microscopy.  The strategies required to mineralize the as-fabricated 3D chitosan hydrogel-based scaffolds via the McGrath method, such that the mineralization achieved within the 3D scaffolds is similar to that obtained within 2D films, were elucidated. This included the use of polyacrylic acid (PAA), a crystal growth modifier. PAA has previously been shown to be important in achieving a pancake-like calcium carbonate formation, comprised of laterally growing nanoparticle aggregates which form in association with the organic matrix, in 2D films; such structures are observed in the early stages of nacre formation. By modulating the period of exposure of the 3D scaffolds to the mineralization solutions and the concentrations of these solutions, it was found that 3D composites with up to 40% calcium carbonate content and varying crystal morphology could be fabricated using this mineralization method. Importantly, it was observed that the calcium carbonate crystallites were intricately associated with the organic hydrogel matrix. This is another essential element observed in biomineral systems. Various techniques such as scanning electron microscopy (SEM), thermogravimetric analysis (TGA), energy dispersive spectroscopy (EDS) and X-ray diffraction (XRD) were employed for structural and compositional characterisation of the final composites.  The prospect of fabricating 3D chitosan-calcium carbonate composites via a single-step method using chitosan hydrogel preloaded with calcium carbonate crystallites as the printing ink in our custom-designed 3D printer was also investigated. This method was studied as a faster and less labour-intensive alternative to developing composites via the two-step method devised in this research whereby 3D hydrogel-based scaffolds are printed first and then mineralized via the McGrath method. The advantages and disadvantages of the two fabrication techniques are compared. The two-step fabrication method was found to be superior in terms of the properties explored and desired in the composite.  The behaviour of the chitosan hydrogel-based scaffolds and composites fabricated using the McGrath method, under different stress and strain regimes were also investigated. Mechanical tests performed on air-dried chitosan hydrogel-based scaffolds and composites showed that the compressive modulus, strength and indentation hardness values obtained were within the same order of magnitude as that of trabecular bone. Data from uniaxial compression tests showed that the yield, ultimate strength and compressive modulus of the 3D scaffolds vary with the total mineral content, morphology and size of the resultant crystallites in the composite. Composites with very low mineral content (~7% CaCO₃ content) showed the best mechanical properties under uniaxial compressive stress (approximately 0.37 GPa compressive modulus, 26 MPa yield strength, and 31 MPa ultimate strength). Nanoindentation tests showed that the nanoscale hardness and indentation modulus increased upon mineralization of the scaffolds but did not vary significantly as a function of the extent of mineralization. Dynamic mechanical analysis showed that the scaffolds (both mineralized and non-mineralized) can effectively dissipate stress without complete fracture when subjected to dynamic compressions within physiologically relevant loading frequencies (1 - 15 Hz) irrespective of the mineral content. The individual responses vary with loading frequency.  Having ascertained the structural and mechanical attributes of the fabricated materials, their capacity to enable osteoblast cell attachment and proliferation was explored. Alamar Blue assay and confocal microscopy performed at various time points for samples exposed to in vitro cultured osteoblasts showed that chitosan hydrogel-based scaffolds and composites are biologically non-toxic and facilitate cell adhesion and proliferation. Furthermore, when osteoblasts were incubated with composites with low CaCO₃ content, the number of cells increased significantly within 14 days.  The results of this research confirm that 3D printed chitosan hydrogel-based composites fabricated using the McGrath mineralization method featuring various structural and compositional imitations of bone and nacre shows considerable potential as future bone grafts materials.</p>


2019 ◽  
Vol 10 (1) ◽  
pp. 12 ◽  
Author(s):  
Mima Kurian ◽  
Ross Stevens ◽  
Kathryn McGrath

A synthetic technique inspired by the biomineralisation process in nacre has been previously reported to be effective in replicating the nanostructural elements of nacre in 2D chitosan hydrogel films. Here we evaluate the applicability of this synthetic biomineralisation technique, herein called the McGrath method, in replicating the flat tabular morphology of calcium carbonate and other nanostructural elements obtained when 2D chitosan hydrogel films were used, on a 3D porous chitosan hydrogel-based scaffold, hence developing 3D chitosan-calcium carbonate composites. Nozzle extrusion-based 3D printing technology was used to develop 3D porous scaffolds using chitosan hydrogel as the printing ink in a custom-designed 3D printer. The rheology of the printing ink and print parameters were optimised in order to fabricate 3D cylindrical structures with a cubic lattice-based internal structure. The effects of various dehydration techniques, including air-drying, critical point-drying and freeze-drying, on the structural integrity of the as-printed scaffolds from the nano to macroscale, were evaluated. The final 3D composite materials were characterised using scanning electron microscopy, X-ray diffraction and energy dispersive X-ray spectroscopy. The study has shown that McGrath method can be used to develop chitosan-calcium carbonate composites wherein the mineral and matrix are in intimate association with each other at the nanoscale. This process can be successfully integrated with 3D printing technology to develop 3D compartmentalised polymer-mineral composites.


Author(s):  
Mahima Singh ◽  
Sriramakamal Jonnalagadda

AbstractThis study evaluates the suitability of 3D printed biodegradable mats to load and deliver the topical antibiotic, neomycin, for up to 3 weeks in vitro. A 3D printer equipped with a hot melt extruder was used to print bandage-like wound coverings with porous sizes appropriate for cellular attachment and viability. The semicrystalline polyester, poly-l-lactic acid (PLLA) was used as the base polymer, coated (post-printing) with polyethylene glycols (PEGs) of MWs 400 Da, 6 kDa, or 20 kDa to enable manipulation of physicochemical and biological properties to suit intended applications. The mats were further loaded with a topical antibiotic (neomycin sulfate), and cumulative drug-release monitored for 3 weeks in vitro. Microscopic imaging as well as Scanning Electron Microscopy (SEM) studies showed pore dimensions of 100 × 400 µm. These pore dimensions were achieved without compromising mechanical strength; because of the “tough” individual fibers constituting the mat (Young’s Moduli of 50 ± 20 MPa and Elastic Elongation of 10 ± 5%). The in vitro dissolution study showed first-order release kinetics for neomycin during the first 20 h, followed by diffusion-controlled (Fickian) release for the remaining duration of the study. The release of neomycin suggested that the ability to load neomycin on to PLLA mats increases threefold, as the MW of the applied PEG coating is lowered from 20 kDa to 400 Da. Overall, this study demonstrates a successful approach to using a 3D printer to prepare porous degradable mats for antibiotic delivery with potential applications to dermal regeneration and tissue engineering.


Polymers ◽  
2021 ◽  
Vol 13 (9) ◽  
pp. 1394
Author(s):  
Yong Sang Cho ◽  
So-Jung Gwak ◽  
Young-Sam Cho

In this study, we investigated the dual-pore kagome-structure design of a 3D-printed scaffold with enhanced in vitro cell response and compared the mechanical properties with 3D-printed scaffolds with conventional or offset patterns. The compressive modulus of the 3D-printed scaffold with the proposed design was found to resemble that of the 3D-printed scaffold with a conventional pattern at similar pore sizes despite higher porosity. Furthermore, the compressive modulus of the proposed scaffold surpassed that of the 3D-printed scaffold with conventional and offset patterns at similar porosities owing to the structural characteristics of the kagome structure. Regarding the in vitro cell response, cell adhesion, cell growth, and ALP concentration of the proposed scaffold for 14 days was superior to those of the control group scaffolds. Consequently, we found that the mechanical properties and in vitro cell response of the 3D-printed scaffold could be improved by kagome and dual-pore structures through DfAM. Moreover, we revealed that the dual-pore structure is effective for the in vitro cell response compared to the structures possessing conventional and offset patterns.


2020 ◽  
Vol 17 (03) ◽  
pp. 2050010
Author(s):  
Saeed Saeedvand ◽  
Hadi S. Aghdasi ◽  
Jacky Baltes

Although there are several popular and capable humanoid robot designs available in the kid-size range, they lack some important characteristics: affordability, being user-friendly, using a wide-angle camera, sufficient computational resources for advanced AI algorithms, and mechanical robustness and stability are the most important ones. Recent advances in 3D printer technology enables researchers to move from model to physical implementation relatively easy. Therefore, we introduce a novel fully 3D printed open platform humanoid robot design named ARC. In this paper, we discuss the mechanical structure and software architecture. We show the capabilities of the ARC design in a series of experimental evaluations.


2019 ◽  
Vol 964 ◽  
pp. 240-245 ◽  
Author(s):  
Amaliya Rasyida ◽  
Thalyta Rizkha Pradipta ◽  
Sigit Tri Wicaksono ◽  
Vania Mitha Pratiwi ◽  
Yeny Widya Rakhmawati

Utilization of brown algae especially in Madura, where it’s close to Surabaya, only limited for food. This become a reference for developing and increasing the potential of this algae by extracting one of the ingredients, namely alginate. This paper deals with the characterization of sodium alginate extracted from sargassum sp. using modified-purified calcium routes. The extracted sodium alginate will be further used as composite hydrogel materials and compared with commercial sodium alginate. Hereafter, the synthesized composite is expected to be bio-ink for 3d printer. Chemical composition analysis were analyzed using X-Ray Fluorosense (XRF) followed by Fourier-transform infrared spectroscopy (FTIR) analysis to identify the functional group of composite and X-Ray Diffraction (XRD). Furthermore, viscosity bath is performed to compare the viscosity of extracted and commercial one. The result shows that modified-purified calcium routes in the extraction process of sodium alginate is desirable for improving their properties. Interestingly enough, with the goal of using it as bio-ink in 3d printed fabrication, the synthesized composite shows viscosity, 300 cSt, which meets the criteria for bio-ink in 3d printer.


2008 ◽  
Vol 589 ◽  
pp. 421-425 ◽  
Author(s):  
Norbert Krisztián Kovács ◽  
József Gábor Kovács

Characteristics of 3D printed specimens are porous structure and low mechanical strength. Due to porous structure post treatment is possible, and in most cases infiltration with an epoxy resin, wax or cyanoacrylate material takes place. As a result of post treatment, the mechanical strength can be increased by 100%, although this is strongly influenced by the infiltration depth that depends on the porous structure and the resin viscosity. In the framework of the common research of the Department of Polymer Engineering, BME and Varinex Zrt. the applicability of a 3D printer is examined in the field of direct tool making. As the first step, the resin uptake ability of specimens prepared with a Z810 3D printer is examined.


2021 ◽  
Vol 26 (1) ◽  
Author(s):  
Lukas Postl ◽  
Thomas Mücke ◽  
Stefan Hunger ◽  
Oliver Bissinger ◽  
Michael Malek ◽  
...  

Abstract Background The accuracy of computer-assisted biopsies at the lower jaw was compared to the accuracy of freehand biopsies. Methods Patients with a bony lesion of the lower jaw with an indication for biopsy were prospectively enrolled. Two customized bone models per patient were produced using a 3D printer. The models of the lower jaw were fitted into a phantom head model to simulate operation room conditions. Biopsies for the study group were taken by means of surgical guides and freehand biopsies were performed for the control group. Results The deviation of the biopsy axes from the planning was significantly less when using templates. It turned out to be 1.3 ± 0.6 mm for the biopsies with a surgical guide and 3.9 ± 1.1 mm for the freehand biopsies. Conclusions Surgical guides allow significantly higher accuracy of biopsies. The preliminary results are promising, but clinical evaluation is necessary.


Author(s):  
E K Nezhurina ◽  
P A Karalkin ◽  
V S Komlev ◽  
I K Sviridova ◽  
V A Kirsanova ◽  
...  

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