References
- Do AV , KhorsandB, GearySM, SalemAK. 3D printing of scaffolds for tissue regeneration applications. Adv. Healthc. Mater.4(12), 1742–1762 (2015).
- Sabban R , BahlS, ChatterjeeK, SuwasS. Globularization using heat treatment in additively manufactured Ti-6Al-4V for high strength and toughness. Acta Mater.162, 239–254 (2019).
- Jaidev L , ChatterjeeK. Surface functionalization of 3D printed polymer scaffolds to augment stem cell response. Mater. Des.161, 44–54 (2019).
- Do AV , WorthingtonKS, TuckerBA, SalemAK. Controlled drug delivery from 3D printed two-photon polymerized poly (ethylene glycol) dimethacrylate devices. Int. J. Pharm.552(1–2), 217–224 (2018).
- Do AV , AkkouchA, GreenBet al. Controlled and sequential delivery of fluorophores from 3D printed alginate–PLGA tubes. Ann. Biomed. Eng.45(1), 297–305 (2017).
- 3D SYSTEMS INC: US4575330 (1986).
- Lee JS , HongJM, JungJW, ShimJH, OhJH, ChoDW. 3D printing of composite tissue with complex shape applied to ear regeneration. Biofabrication6(2), 024103 (2014).
- Goyanes A , KobayashiM, Martinez-PachecoR, GaisfordS, BasitAW. Fused-filament 3D printing of drug products: microstructure analysis and drug release characteristics of PVA-based caplets. Int. J. Pharm.514(1), 290–295 (2016).
- Brunello G , SivolellaS, MeneghelloRet al. Powder-based 3D printing for bone tissue engineering. Biotechnol. Adv.34(5), 740–753 (2016).
- Wu BM , BorlandSW, GiordanoRA, CimaLG, SachsEM, CimaMJ. Solid free-form fabrication of drug delivery devices. J. Control. Rel.40(1–2), 77–87 (1996).
- Timashev P , VedunovaM, GusevaDet al. 3D in vitro platform produced by two-photon polymerization for the analysis of neural network formation and function. Biomed. Phys. Eng. Express2(3), 035001 (2016).
- Worthington KS , WileyLA, KaalbergEEet al.Two-photon polymerization for production of human iPSC-derived retinal cell grafts. Acta Biomater.55, 385–395 (2017).
- Do AV , GearySM, SeolDet al.Combining ultrasound and intratumoral administration of doxorubicin-loaded microspheres to enhance tumor cell killing. Int. J. Pharm.539(1–2), 139–146 (2018).
- Ebeid K , MengX, ThielKWet al.Synthetically lethal nanoparticles for treatment of endometrial cancer. Nat. Nanotechnol.13(1), 72–81 (2018).
- Intra J , GlasgowJM, MaiHQ, SalemAK. Pulsatile release of biomolecules from polydimethylsiloxane (PDMS) chips with hydrolytically degradable seals. J. Control. Rel.127(3), 280–287 (2008).
- Terry TL , GivensBE, RodgersVG, SalemAK. Tunable properties of poly-DL-lactide-monomethoxypolyethylene glycol porous microparticles for sustained release of polyethylenimine–DNA polyplexes. AAPS PharmSciTech20(1), 23 (2019).
- Wafa E , GearyS, RossK, GoodmanJ, NarasimhanB, SalemA. Single dose of polyanhydride particle-based vaccine generates potent antigen-specific antitumor immune responses. J. Pharmacol. Exp. Ther. (2018). (Epub ahead of print).
- Melchels FP , FeijenJ, GrijpmaDW. A review on stereolithography and its applications in biomedical engineering. Biomaterials31(24), 6121–6130 (2010).
- Bozuyuk U , YasaO, YasaIC, CeylanH, KizilelS, SittiM. Light-triggered drug release from 3D-printed magnetic chitosan microswimmers. ACS Nano12(9), 9617–9625 (2018).
- Son AI , OpfermannJD, McCueCet al.An implantable micro-caged device for direct local delivery of agents. Sci. Rep.7(1), 17624 (2017).