Natural and Synthetic Polymer Fillers for Applications in 3D Printing—FDM Technology Area

Sztorch, Bogna; Brząkalski, Dariusz; Pakuła, Daria; Frydrych, Miłosz; Špitálský, Zdenko; Przekop, Robert E.

doi:10.3390/solids3030034

Cited by 36 publications

(16 citation statements)

References 270 publications

(279 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…cellulose), generally with an intrinsic fibrillar structure [127] and synthetic polymers (polyamide or polyester). Inorganic compounds include oxides and hydroxides (Al(OH) 3 , Mg(OH) 2 , TiO 2 , Fe 3 O 4 ), salts (CaCO 3 , BaSO 4 ), metals and silicates [125].…”

Section: Fillersmentioning

confidence: 99%

Chemistry in light-induced 3D printing

et al. 2023

View full text Add to dashboard Cite

In the last few years, 3D printing has evolved from its original niche applications, such as rapid prototyping and hobbyists, towards many applications in industry, research and everyday life. This involved an evolution in terms of equipment, software and, most of all, in materials. Among the different available 3D printing technologies, the light activated ones need particular attention from a chemical point of view, since those are based on photocurable formulations and in situ rapid solidification via photopolymerization. In this article, the chemical aspects beyond the preparation of a formulation for light-induced 3D printing are analyzed and explained, aiming at giving more tools for the development of new photocurable materials that can be used for the fabrication of innovative 3D printable devices. Graphical abstract

show abstract

Section: Fillersmentioning

confidence: 99%

Chemistry in light-induced 3D printing

et al. 2023

View full text Add to dashboard Cite

show abstract

“…The mesoporous structure of the SrBG sample was also confirmed by XRD analysis. Indeed, in the low angle region, the XRD pattern of SrBG (Figure S1d) shows Bragg peaks/shoulders at 2h&2.4, 4.2 and 4.9°, revealing an ordered hexagonal network of mesopores (space group p6mm, d 10 = 3.65 nm, lattice parameter a 0 = 4.2 nm) [63][64][65][66][67]. On the other hand, the wide-angle XRD pattern of the calcined Sr-containing bioglass depicted in Figure S1e points to orthorhombic symmetry (Space Group: Pmcn) and is mainly related to the strontium carbonate (SrCO 3 ) strontianite phase [57,58] as observed upon comparing the powder profile with the expected peak positions (PDF No: 5-418).…”

Section: Characterization Of Srbgmentioning

confidence: 99%

“…Oftentimes, when preparing thermoplastic composite filaments with bioglass or HA, the composites are prepared beforehand using the solution mixing approach using organic solvents to ensure good filler dispersion [56,65,66], since the hydrophilic ceramics are incompatible with hydrophobic polymers. Additionally, adding a sufficient quantity of fillers in order to get enough particles on the surface of the filaments and obtaining the desired hydrophilicity can deteriorate printing quality [67,68]. With the coating approach, only water is used as a solvent and all the bioactive particles are located on the surface of the scaffolds, while when adding them in the filament only a handful of surface particles can be detected [69][70][71].…”

Section: Preparation and Characterization Of 3d Printed Scaffoldsmentioning

confidence: 99%

3D printed poly(lactic acid)-based nanocomposite scaffolds with bioactive coatings for tissue engineering applications

et al. 2023

View full text Add to dashboard Cite

In this work, the effect of two different types of bioactive coatings on the properties of 3D printed poly(lactic acid)/montmorillonite (PLA/MMT) nanocomposite scaffolds was examined. To improve their suitability for bone tissue engineering applications, the PLA nanocomposite scaffolds were coated with (i) ordered mesoporous Strontium bioglass (SrBG) and (ii) SrBG and nanohydroxyapatite (nHA) using a simple dip coating procedure. The effect of the coatings on the morphology, chemical structure, wettability and nanomechanical properties of the scaffolds was examined. The hydrophilicity of PLA nanocomposite scaffolds increased after the SrBG coating and increased even more with the SrBG/nHA coating. Moreover, in the case of PLA/MMT/SrBG/nHA 3D printed scaffolds, the elastic modulus increased by ~ 80% and the hardness increased from 156.9 ± 6.4 to 293.6 ± 11.3 MPa in comparison with PLA. Finally, the in vitro biocompatibility and osteogenic potential were evaluated using bone marrow-derived stem cells. The coating process was found to be a fast, economical and effective way to improve the biomineralization and promote the differentiation of the stem cells toward osteoblasts, in comparison with the neat PLA and the PLA/MMT nanocomposite scaffold. Graphical abstract

show abstract

“…The resulting polymer composites can be manufactured into production-ready 3D printing filaments. 15,22 Glass beads and iron particles have previously been used in 3D printing filaments with success. 23−27 Glass has been used as a mechanical reinforcement in polymers for decades as both fibers and hollow/solid glass beads.…”

Section: ■ Introductionmentioning

confidence: 99%

“…Polylactic acid (PLA) and polyethylene terephthalate glycol (PETG) are popular thermoplastics used in additive manufacturing (3D printing) applications. − PLA is commonly used as a 3D printing filament due to its processability, biodegradability, compostability, and recyclability. − PETG is widely used in 3D printing due to its flexibility, processability, and good chemical, moisture, and UV resistance. ,,− The mechanical properties of PLA and PETG can be significantly improved by introducing fillers into the polymer matrix. The resulting polymer composites can be manufactured into production-ready 3D printing filaments. , Glass beads and iron particles have previously been used in 3D printing filaments with success. − …”

Section: Introductionmentioning

confidence: 99%

Micromechanical Dilution of PLA/PETG–Glass/Iron Nanocomposites: A More Efficient Molecular Dynamics Approach

Pisani,

Wedgeworth,

Burroughs

et al. 2024

ACS Omega

View full text Add to dashboard Cite

Polylactic acid (PLA) and poly(ethylene terephthalate glycol) (PETG) are popular thermoplastics used in additive manufacturing applications. The mechanical properties of PLA and PETG can be significantly improved by introducing fillers, such as glass and iron nanoparticles (NPs), into the polymer matrix. Molecular dynamics (MD) simulations with the reactive INTER-FACE force field were used to predict the mechanical responses of neat PLA/PETG and PLA−glass/iron and PETG−glass/iron nanocomposites with relatively high loadings of glass/iron NPs. We found that the iron and glass NPs significantly increased the elastic moduli of the PLA matrix, while the PETG matrix exhibited modest increases in elastic moduli. This difference in reinforcement ability may be due to the slightly greater attraction between the glass/iron NP and PLA matrix. The NASA Multiscale Analysis Tool was used to predict the mechanical response across a range of volume percent glass/iron filler by using only the neat and highly loaded MD predictions as input. This provides a faster and more efficient approach than creating multiple MD models per volume percent per polymer/filler combination. To validate the micromechanics predictions, experimental samples incorporating hollow glass microspheres (MS) and carbonyl iron particles (CIP) into PLA/PETG were developed and tested for elastic modulus. The CIP produced a larger reinforcement in elastic modulus than the MS, with similar increases in elastic modulus between PLA/CIP and PETG/CIP at 7.77 vol % CIP. The micromechanics-based mechanical predictions compare excellently with the experimental values, validating the integrated micromechanical/MD simulation-based approach.

show abstract

Natural and Synthetic Polymer Fillers for Applications in 3D Printing—FDM Technology Area

Cited by 36 publications

References 270 publications

Chemistry in light-induced 3D printing

Chemistry in light-induced 3D printing

3D printed poly(lactic acid)-based nanocomposite scaffolds with bioactive coatings for tissue engineering applications

Micromechanical Dilution of PLA/PETG–Glass/Iron Nanocomposites: A More Efficient Molecular Dynamics Approach

Contact Info

Product

Resources

About