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Baier, R.V.; Raggio, J.I.C.; Arancibia, C.T.; Bustamante, M.; Perez, L.; Burda, I.; Aiyangar, A.; Vivanco, J.F. |
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Structure-function assessment of 3D-printed porous scaffolds by a low-cost/ open source fused filament fabrication printer |
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2021 |
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Materials Science & Engineering C-Materials For Biological Applications |
Abbreviated Journal |
Mater. Sci. Eng. C-Mater. Biol. Appl. |
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123 |
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111945 |
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Keywords |
3D printer; Scaffold; Fused filament fabrication; Mechanical properties; Finite element method; Cell adhesion efficiency |
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Additive manufacturing encompasses a plethora of techniques to manufacture structures from a computational model. Among them, fused filament fabrication (FFF) relies on heating thermoplastics to their fusion point and extruding the material through a nozzle in a controlled pattern. FFF is a suitable technique for tissue engineering, given that allows the fabrication of 3D-scaffolds, which are utilized for tissue regeneration purposes. The objective of this study is to assess a low-cost/open-source 3D printer (In-House), by manufacturing both solid and porous samples with relevant microarchitecture in the physiological range (100?500 ?m pore size), using an equivalent commercial counterpart for comparison. For this, compressive tests in solid and porous scaffolds manufactured in both printers were performed, comparing the results with finite element analysis (FEA) models. Additionally, a microarchitectural analysis was done in samples from both printers, comparing the measurements of both pore size and porosity to their corresponding computer-aided design (CAD) models. Moreover, a preliminary biological assessment was performed using scaffolds from our In-House printer, measuring cell adhesion efficiency. Finally, Fourier transform infrared spectroscopy ? attenuated total reflectance (FTIR?ATR) was performed to evaluate chemical changes in the material (polylactic acid) after fabrication in each printer. The results show that the In-House printer achieved generally better mechanical behavior and resolution capacity than its commercial counterpart, by comparing with their FEA and CAD models, respectively. Moreover, a preliminary biological assessment indicates the feasibility of the In-House printer to be used in tissue engineering applications. The results also show the influence of pore geometry on mechanical properties of 3D-scaffolds and demonstrate that properties such as the apparent elastic modulus (Eapp) can be controlled in 3D-printed scaffolds. |
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0928-4931 |
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WOS:000636846700007 |
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UAI @ alexi.delcanto @ |
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1367 |
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Dreyer, M.J.; Weisse, B.; Raggio, J.I.C.; Zboray, R.; Taylor, W.R.; Preiss, S.; Horn, N. |
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Title |
The influence of implant design and limb alignment on in vivo wear rates of fixed-bearing and rotating-platform knee implant retrievals |
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2023 |
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Journal of Orthopaedic Research |
Abbreviated Journal |
J. Orthop. Res. |
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Early Access |
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3D scanning; arthroplasty; knee implant; retrievals; wear |
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Abstract |
Analysis of polyethylene (PE) wear in knee implants is crucial for understanding the factors leading to revision in total knee arthroplasty. Importantly, current experimental and computational methods for predicting insert wear can only be validated against true in vivo measurements from retrievals. This study quantitatively investigated in vivo PE wear rates in fixed-bearing (FB) (n = 21) and rotating-platform (n = 53) implant retrievals. 3D surface geometry of the retrievals was measured using a structured light scanner. Then, a reference surface that included the deformation, but not the wear that the retrievals had experienced in vivo, was constructed using a fully automatic surface reconstruction algorithm. Finally, wear volume was calculated from the deviation between the worn and reconstructed surfaces. The measurement and analysis techniques were validated and the algorithm was found to produce errors of only 0.2% relative to the component volumes. In addition to quantifying cohort-level wear rates, the effect of mechanical axis limb alignment on mediolateral wear distribution was examined for a subset of the retrievals (n = 14 + 26). Our results show that FB implants produce significantly (p = 0.04) higher topside wear rates (24.6 +/- 10.1 mm3/year) than rotating-platform implants (15.3 +/- 8.0 mm3/year). This effect was larger than that of limb alignment, which had a smaller and nonsignificant influence on overall wear rates (+4.5 +/- 11.6 mm3/year, p = 0.43). However, increased varus alignment was associated significantly with greater medial compartment wear in both the FB and rotating-platform designs (+1.7 +/- 1.3%/degrees and +1.8 +/- 1.6%/degrees). Our findings emphasize the importance of implant design and limb alignment on wear outcomes, providing reference data for improving implant performance and longevity. |
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0736-0266 |
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WOS:001111164700001 |
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UAI @ alexi.delcanto @ |
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1920 |
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