Development of sustainable PCL/rice husk–derived SiO 2 composites through fused filament fabrication: Mechanical,degradation,and antibacterial performance
Restricted accessResearch articleFirst published online 2026
Development of sustainable PCL/rice husk–derived SiO 2 composites through fused filament fabrication: Mechanical,degradation,and antibacterial performance
Polycaprolactone (PCL) is widely employed in fused filament fabrication (FFF) for biomedical applications; however, its mechanical strength, hydrophobic nature of the surface, and lack of antimicrobial property are the barriers to its wider use. The rice husk–derived amorphous silica (RH-SiO2), acquired through a sustainable waste valorization route was incorporated with PCL to fabricate multifunctional composites using FFF. The composite filaments with different contents of RH-SiO2 were extruded and printed, followed by a series of tests on melt flow behavior, dimensional stability, thermal characteristics, mechanical performance, wettability, in vitro degradation, and antibacterial activity. The results of microstructural analysis showed the filler was well dispersed. The optimal 2 wt% RH-SiO2 reinforcement led to an impressive enhancement of tensile strength (9.95 MPa), compressive strength (29.32 MPa), and surface hardness due to the synergistic effects of increased crystallinity and controlled melt rheology. The change in the contact angle showed a dramatic increase in wettability, while the results of degradation studies indicated that there was a balanced and stable degradation profile with very little pH variation. The printed PCL/RH-SiO2 composites has a compressive strength within the required range of trabecular bone, making it suitable for biomedical scaffold applications.
KumarSSinghRSinghTP, et al.Fused filament fabrication: a comprehensive review. J Thermoplast Compos Mater2023; 36: 794–814. https://doi.org/10.1177/0892705720970629
2.
AciernoD. Fused deposition modelling (FDM) of thermoplastic-based filaments: process and rheological properties—an overview, 2023. https://www.mdpi.com/1996-1944/16/24/7664 (accessed 11 May 2026).
3.
Grivet-BrancotABoffitoMCiardelliG. Use of polyesters in fused deposition modeling for biomedical applications. Wiley Online Library2022; 22: 2200039. https://doi.org/10.1002/MABI.202200039, Epub ahead of print 1.
4.
PaetzoldRCoulterFSinghG, et al.Fused filament fabrication of polycaprolactone bioscaffolds: influence of fabrication parameters and thermal environment on geometric fidelity and mechanical. Elsevier. https://www.sciencedirect.com/science/article/pii/S2405886622000161 (accessed 11 May 2026).
5.
PattanashettiNBiscaiaSMouraC, et al.Development of novel 3D scaffolds using BioExtruder by the incorporation of silica into polycaprolactone matrix for bone tissue engineering. Elsevier. https://www.sciencedirect.com/science/article/pii/S2352492819303010 (accessed 11 May 2026).
JianKWengFZhangP, et al.Effects of different kinds of shell powder on the structure and properties of polycaprolactone-based composites. J Thermoplast Compos Mater2023; 36: 4349–4364. https://doi.org/10.1177/08927057231154424
BarretoGRestrepoSVieiraC, et al.Rice husk with PLA: 3D filament making and additive manufacturing of samples for potential structural applications. Polymers2024; 16: 245. https://www.mdpi.com/2073-4360/16/2/245 (accessed 11 May 2026).
12.
Le GuenMJHillSSmithDInfluence of rice husk and wood biomass properties on the manufacture of filaments for fused deposition modeling. Frontiers in Chemistry2019; 7: 735. https://doi.org/10.3389/fchem.2019.00735
13.
NaghizadehFSultanaNAbdul KadirMR, et al.The fabrication and characterization of PCL/rice husk derived bioactive glass‐ceramic composite scaffoldsJournal of Nanomaterials2014. https://doi.org/10.1155/2014/253185. Epub ahead of print 2014.
14.
AdamuMSumailaMDaudaM, et al.Production and optimization of novel rice husk ash reinforced polycaprolactone/hydroxyapatite composite for bone regeneration using grey relational analysis. Scientific African2023; 19: e01563. https://www.sciencedirect.com/science/article/pii/S2468227623000224 (accessed 11 May 2026).
15.
NukalaSKongIPatelV, et al.Development of biodegradable composites using polycaprolactone and bamboo powder. Polymers2022; 14: 4169. https://www.mdpi.com/2073-4360/14/19/4169 (accessed 11 May 2026).
16.
Qin-huiCXue-fangLJin-huoL. Preparation and properties of biodegradable bamboo powder/polycaprolactone composites. Springer, 2009, vol 20, pp. 271–274.
17.
BhagabatiPDasDAdvancesVK-M, et al.Bamboo-flour-filled cost-effective poly (ε-caprolactone) biocomposites: a potential contender for flexible cryo-packaging applications. Materials Advances2021; 2: 280–291. https://pubs.rsc.org/en/content/articlehtml/2020/ma/d0ma00517g (accessed 11 May 2026).
MohammedM. R.Mechanical and biological behaviour of 3D printed PCL-based scaffolds fabricated by fused deposition modelling for bone tissue engineering: a review of recent advances. Journal of Engineering Sciences2022; 1: 33-46. https://pdfs.semanticscholar.org/0e3d/e1a3e93fb06d2bcb6891ec3f935ddda4e35a.pdf(accessed 11 May 2026).
20.
ArunprasandTMaterials PN-M of A, 2025 undefined. Advancements in optimizing mechanical performance of 3d printed polymer matrix composites via microstructural refinement and processing enhancements. Mechanics of Advanced Materials and Structures2025; 32: 5616–5634.
21.
JiaPLiuXLiG, et al.Sol–gel synthesis and characterization of SiO2@CaWO4,SiO2@CaWO4:Eu3+/Tb3+ core–shell structured spherical particles. Nanotechnology2006; 17: 734. https://doi.org/10.1088/0957-4484/17/3/020/META
22.
HuangHScience JZ-J of AP. 2009 undefined. Effects of filler–filler and polymer–filler interactions on rheological and mechanical properties of HDPE–wood composites. Journal of Applied Polymer Science2009; 111: 2806–2812.
23.
AdamuMASumailaMDaudaMA novel polycaprolactone/rice husk ash/hydroxyapatite biopolymer composite for bone implant: physico-mechanical and biodegradable analysis. Iranian Polymer Journal2024; 33: 395–404. https://doi.org/10.1007/s13726-023-01248-8
24.
YeongMEnvironmentRK-F. W and, 2023 undefined. Potential use of rise husk as filler in poly lactic acid bio-composite: mechanical properties, morphology and biodegradability. akademiabaru.com. https://akademiabaru.com/submit/index.php/fwe/article/view/3808 (accessed 11 May 2026).
MischCQuZsurgery MB-J of oral and maxillofacial, et al.Mechanical properties of trabecular bone in the human mandible: implications for dental implant treatment planning and surgical placement. Elsevier. https://www.sciencedirect.com/science/article/pii/S0278239199904378 (accessed 11 May 2026).
28.
Grząbka-ZasadzińskaAAP-IJ of, 2024 undefined. Structure and properties of polylactide composites with TiO2–Lignin hybrid fillers. International Journal of Molecular Sciences2024; 25: 4398. https://www.mdpi.com/1422-0067/25/8/4398 (accessed 11 May 2026).
29.
GaneshNJayakumarRKoyakuttyM, et al.Embedded silica nanoparticles in poly (caprolactone) nanofibrous scaffolds enhanced osteogenic potential for bone tissue engineering. Tissue Engineering Part A2012; 18: 1867–1881. https://doi.org/10.1089/ten.TEA.2012.0167
AnaIVranaNMoritaA, et al.Antibacterial surface functionalization of biomedical scaffolds: a transformation towards more adaptive, resilient regenerative therapy. Results in Surfaces and Interfaces2025. https://www.sciencedirect.com/science/article/pii/S2666845925000686 (accessed 11 May 2026).
32.
KokkaracheduVChandrasekaranKSisubalanN, et al.SiO2-Based nanomaterials as antibacterial and antiviral agents: potential applications. In: Nanoparticles in Modern Antimicrobial and Antiviral Applications, 2024; 65–95.
33.
KapaliBSCKumarUSMaheswariSU, et al.Evaluation of additively manufactured PLA-proso millet husk biosilica biocomposite and its mechanical performance as human prosthetic clavicle in bone. Journal of the Australian Ceramic Society2025; 61: 2061–2071.
34.
LyubushkinR. Polylactide-based polymer composites with rice husk filler. Journal of Composites Science2024, Undefined. https://www.mdpi.com/2504-477X/8/10/427 (accessed 11 May 2026).
