https://orcid.org/0000-0002-5307-3743
References
- TrenfieldSJ, AwadA, GoyanesA, GaisfordS, BasitAW. 3D printing pharmaceuticals: drug development to frontline care. Trends Pharmacol. Sci.39(5), 440–451 (2018).
- SillaniF, WagnerD, SpurekMA, HaferkampL, SpieringsAB, SchmidMet al.Compaction behavior of powder bed fusion feedstock for metal and polymer additive manufacturing. Rapid Prototyp J.27(11), 58–66 (2021).
- BrighentiR, CosmaMP, MarsavinaL, SpagnoliA, TerzanoM. Laser-based additively manufactured polymers: a review on processes and mechanical models. J. Mater. Sci.56(2), 961–998 (2021).
- LuponeF, PadovanoE, CasamentoF, BadiniC. Process phenomena and material properties in selective laser sintering of polymers: a review. Materials (Basel).15(1), 183 (2021).
- Okafor-MuoOL, HassaninH, KayyaliR, ElShaerA. 3D printing of solid oral dosage forms: numerous challenges with unique opportunities. J. Pharm. Sci.109(12), 3535–3550 (2020).
- CharooNA, BarakhAli SF, MohamedEM, KuttolamadomMA, OzkanT, KhanMAet al.Selective laser sintering 3D printing - an overview of the technology and pharmaceutical applications. Drug Dev. Ind. Pharm.46(6), 869–877 (2020).
- AwadA, FinaF, GoyanesA, GaisfordS, BasitAW. 3D printing: principles and pharmaceutical applications of selective laser sintering. Int. J. Pharm.586(119594), 119594 (2020).
- KaranwadT, LekurwaleS, BanerjeeS. Selective Laser Sintering (SLS) in Pharmaceuticals. In: Additive Manufacturing in Pharmaceuticals.Springer Nature, Singapore (2023).
- KumarMB, SathiyaP, VaratharajuluM. Selective laser sintering. In: Advances in Additive Manufacturing Processes.China Bentham Books, Beijing, China (2021).
- Sinterit.com. (2023). https://sinterit.com/wp-content/uploads/2021/12/LISA-1.5_full-user-manual_1.5.pdf
- LekurwaleS, KaranwadT, BanerjeeS. Selective laser sintering (SLS) of 3D printlets using a 3D printer comprised of IR/red-diode laser. Annals of 3D Printed Medicine.6(100054), 100054 (2022).
- MadžarevićM, MedarevićÐ, PavlovićS, IvkovićB, ÐurišJ, IbrićS. Understanding the effect of energy density and formulation factors on the printability and characteristics of SLS irbesartan tablets-application of the decision tree model. Pharmaceutics.13(11), 1969 (2021).
- GuecheYA, Sanchez-BallesterNM, BatailleB, AubertA, RossiJ-C, SoulairolI. A QbD approach for evaluating the effect of selective laser sintering parameters on printability and properties of solid oral forms. Pharmaceutics.13(10), 1701 (2021).
- GuecheYA, Sanchez-BallesterNM, CailleauxS, BatailleB, SoulairolI. Selective laser sintering (SLS), a new chapter in the production of solid oral forms (SOFs) by 3D printing. Pharmaceutics.13(8), 1212 (2021).
- TrenfieldSJ, JanuskaiteP, GoyanesA, WilsdonD, RowlandM, GaisfordSet al.Prediction of solid-state form of SLS 3D printed medicines using NIR and Raman spectroscopy. Pharmaceutics.14(3), 589 (2022).
- MwaniaFM, MaringaM, vander Walt JG. A review of the techniques used to characterize laser sintering of polymeric powders for use and re-use in additive manufacturing. Manuf Rev (Les Ulis).8, 14 (2021).
- ImanianME, BiglariFR. Modeling and prediction of surface roughness and dimensional accuracy in SLS 3D printing of PVA/CB composite using the central composite design. J. Manuf. Process.75, 154–169 (2022).
- GvS, FeV, GbG, MsM, LaK. 3D printing of PCL/Fluorouracil tablets by selective laser sintering: properties of implantable drug delivery for cartilage cancer treatment. Rheumatol. Orthop. Med.2(3), (2017). http://dx.doi.org/10.15761/rom.1000121
- SalmoriaGV, CardenutoMR, RoeslerCRM, ZeponKM, KanisLA. PCL/ibuprofen implants fabricated by selective laser sintering for orbital repair. Procedia CIRP.49, 188–192 (2016).
- LeongKF, ChuaCK, GuiWS, Verani. Building porous biopolymeric microstructures for controlled drug delivery devices using selective laser sintering. Int. J. Adv. Manuf. Technol.31(5–6), 483–489 (2006).