Personalized solutions for ENT implants

The role of 3D/4D printing

Authors

  • Jigar Vyas Krishna School of Pharmacy and Research, Vadodara, India https://orcid.org/0000-0001-8044-7002
  • Nensi Raytthatha Research Scholar, Gujarat Technological University, Ahmedabad, India
  • Puja Vyas Faculty of Pharmacy, Sigma University, Vadodara, India
  • Jitendra Patel Faculty of Pharmacy, Sigma University, Vadodara, India

DOI:

https://doi.org/10.1590/

Keywords:

ENT implant, 3D printing, 4D printing, Additive manufacturing, Bioprinting, Biomaterials, Smart polymers, Tissue engineering

Abstract

3D printing, a newer manufacturing technology, is gaining prominence in the pharmaceutical and healthcare sectors, particularly ENT implants. It enables the production of customized biological tissue scaffolds, portable models, and surgical training aids. The emergence of 4D printing offers the potential for enhancing ENT therapy safety and efficacy. The manuscript explores the potential of 3D printing to revolutionize pharmaceutical and clinical practice, enabling the development of personalized drug formulations, patient-centric implants, and anatomical models. This review delves into the emerging concept of “smart” biomaterials used in 4D printing, which are capable of mimicking natural tissues and responding to external stimuli. This paves the way for significant advancements in ENT tissue engineering with the potential to increase treatment safety and efficacy. This highlights the importance of healthcare staff in translating 3D printing innovations into clinical practice for successful adoption. The manuscript highlights the transformative impact of 3D printing in the pharmaceutical and healthcare industries. 3D printing and bioprinting technologies are revolutionizing ENT therapy, offering novel avenues for improved patient care and fostering advancements in the healthcare field.

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References

Adamzyk C, Kachel P, Hoss M, Gremse F, Modabber A, Hölzle F, et al. Bone tissue engineering using polyetherketoneketone scaffolds combined with autologous mesenchymal stem cells in a sheep calvarial defect model. Journal of cranio-maxillo-facial surgery: official publication of the European Association for Cranio-Maxillo-Facial Surgery. 2016;44(8):985-94.

Alrasheed AS, Nguyen LHP, Mongeau L, Funnell WRJ, Tewfik MA. Development and validation of a 3D-printed model of the ostiomeatal complex and frontal sinus for endoscopic sinus surgery training. International forum of allergy & rhinology. 2017;7(8):837-41.

Álvarez E, Estévez M, Gallo-Cordova A, González B, Castillo RR, Morales MD, et al. Superparamagnetic Iron Oxide Nanoparticles Decorated Mesoporous Silica Nanosystem for Combined Antibiofilm Therapy. Pharmaceutics [Internet]. 2022;14(1).

Arakawa CK, Badeau BA, Zheng Y, DeForest CA. Multicellular Vascularized Engineered Tissues through User-Programmable Biomaterial Photodegradation. Advanced Materials 2017;29.

Brennan JR, Cornett A, Chang B, Crotts SJ, Nourmohammadi Z, Lombaert I, et al. Preclinical assessment of clinically streamlined, 3D-printed, biocompatible single-and two-stage tissue scaffolds for ear reconstruction. J Biomed Mater Res Part B: Applied Biomaterials. 2021;109(3):394-400.

Chen Q-Z, Li Y, Jin L-Y, Quinn JMW, Komesaroff PA. A new sol-gel process for producing Na2O-containing bioactive glass ceramics. Acta Biomaterialia. 2010;6(10):4143-53.

Chen QZ, Thompson ID, Boccaccini AR. 45S5 Bioglass-derived glass-ceramic scaffolds for bone tissue engineering. Biomaterials. 2006;27(11):2414-25.

Chen Y, Zhang J, Liu X, Wang S, Tao J, Huang Y, et al. Noninvasive in vivo 3D bioprinting. Sci Adv. 2020;6(23):eaba7406.

Conoscenti G, Schneider T, Stoelzel K, Carfì Pavia F, Brucato V, Goegele C, et al. PLLA scaffolds produced by thermally induced phase separation (TIPS) allow human chondrocyte growth and extracellular matrix formation dependent on pore size. Mater Sci Eng C Mater Biol Appl. 2017;80:449-59.

Cui H, Miao S, Esworthy T, Lee S-j, Zhou X, Hann SY, et al. A novel near-infrared light responsive 4D printed nanoarchitecture with dynamically and remotely controllable transformation. Nano Res. 2019;12(6):1381-8.

Daniel M, Watson J, Hoskison E, Sama A. Frontal sinus models and onlay templates in osteoplastic flap surgery. J Laryngol Otol. 2011;125(1):82-5.

Du X, Fu S, Zhu Y. 3D printing of ceramic-based scaffolds for bone tissue engineering: an overview. J Mater Chem B. 2018;6(27):4397-412.

El-Husseiny HM, Mady EA, Hamabe L, Abugomaa A, Shimada K, Yoshida T, et al. Smart/stimuli-responsive hydrogels: Cutting-edge platforms for tissue engineering and other biomedical applications. Mater Today, Today Bio. 2022;13:100186.

Elsner JJ, Zilberman M. Novel antibiotic-eluting wound dressings: an in vitro study and engineering aspects in the dressing’s design. Journal of tissue viability. 2010;19(2):54-66.

Eltom A, Zhong G, Muhammad A. Scaffold Techniques and Designs in Tissue Engineering Functions and Purposes: A Review. Adv Mater Sci Eng. 2019;2019(1):3429527.

Gao B, Jing H, Gao M, Wang S, Fu W, Zhang X, et al. Long-segmental tracheal reconstruction in rabbits with pedicled Tissue-engineered trachea based on a 3D-printed scaffold. Acta biomaterialia. 2019;97:177-86.

Gladman AS, Matsumoto EA, Nuzzo RG, Mahadevan L, Lewis JA. Biomimetic 4D printing. Nature Materials 2016;15:413-8.

Goldstein TA, Smith BD, Zeltsman D, Grande D, Smith LP. Introducing a 3-dimensionally Printed, Tissue-Engineered Graft for Airway Reconstruction: A Pilot Study. Otolaryngology-head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery. 2015;153(6):1001-6.

Goyanes A, Det-Amornrat U, Wang J, Basit AW, Gaisford S. 3D scanning and 3D printing as innovative technologies for fabricating personalized topical drug delivery systems. J Control Release. 2016;234:41-8.

Green R, Abidian MR. Conducting Polymers for neural prosthetic and neural interface applications. Adv Mater. 2015;27(46):7620-37.

Grolman W, Schouwenburg PF, Verbeeten Jr B, de Boer MF, Meeuwis CA. Three-dimensional models of the tracheostoma using stereolithography. ORL; Journal for oto-rhino-laryngology and its related specialties. 1995;57(6):338-42.

Gualtieri T, Taboni S, Ferrari M, Gilbert R. Bioengineering for head and neck reconstruction: the role of customized flaps. Curr Opin Otolaryngol Head Neck Surg. 2021;29(2):156-60.

Güney E, Emir C, Altan D, Yücel S. Development of biocomposite tissue scaffolds of collagen/gelatin/ borondoped bioactive glass prepared through solvent casting/particulate leaching method for bone tissue engineering. J Indian Chem Soc. 2020;97:2006-12.

Harris LD, Kim BS, Mooney DJ. Open pore biodegradable matrices formed with gas foaming. J Biomed Mater Res. 1998;42(3):396-402.

Hinton TJ, Jallerat Q, Palchesko RN, Park JH, Grodzicki MS, Shue H-J, et al. Three-dimensional printing of complex biological structures by freeform reversible embedding of suspended hydrogels. Science Advances. 2015;1(9):e1500758.

Hosseinkhani H, Domb AJ, Sharifzadeh G, Nahum V. Gene therapy for regenerative medicine. Pharmaceutics [Internet]. 2023;15(3).

Jamal M, Kadam SS, Xiao R, Jivan F, Onn TM, Fernandes R, et al. Bio-origami hydrogel scaffolds composed of photocrosslinked PEG bilayers. Adv healthcare mater. 2013;2(8):1142-50.

Jang CH, Koo Y, Kim G. ASC/chondrocyte-laden alginate hydrogel/PCL hybrid scaffold fabricated using 3D printing for auricle regeneration. Carbohydrate polymers. 2020;248:116776.

Jang YS, Jang CH, Cho YB, Kim M, Kim GH. Tracheal regeneration using polycaprolactone/collagen-nanofiber coated with umbilical cord serum after partial resection. International journal of pediatric otorhinolaryngology. 2014;78(12):2237-43.

Javaid M, Haleem A. 4D printing applications in medical field: A brief review. Clin Epidemiol Global Health. 2018;7.

Jeong HY, An S-C, Lim Y, Jeong MJ, Kim N, Jun YC. 3D and 4D Printing of Multistable Structures. Applied Sciences [Internet]. 2020; 10(20).

Jiang J, Chen X, Mei Z, Chen H, Chen J, Wang X, et al. Review of Droplet Printing Technologies for Flexible Electronic Devices: Materials, Control, and Applications. Micromachines [Internet]. 2024;15(3).

Jung S, Lee SJ L, Kim HY, Park HS, Wang Z, Kim HJ, et al. 3D printed polyurethane prosthesis for partial tracheal reconstruction: A pilot animal study. Biofabrication. 2016;8:045015.

Kang HW, Lee SJ, Ko IK, Kengla C, Yoo JJ, Atala A. A 3D bioprinting system to produce human-scale tissue constructs with structural integrity. Nature biotechnology. 2016;34(3):312-9.

Kavanagh KR, Cote V, Tsui Y, Kudernatsch S, Peterson DR, Valdez TA. Pediatric laryngeal simulator using 3D printed models: A novel technique. The Laryngoscope. 2017;127(4):E132-e7.

Khan G, Choi YS, Park ES, Choi YD. The Application of Three-Dimensional Simulation Program and Three-Dimensional Printing in Secondary Rhinoplasty. The Journal of craniofacial surgery. 2018;29(8):e774-e7.

Khoo Z, Teoh J, Liu Y, Chua C, Yang S, An J, et al. 3D printing of smart materials: A review on recent progresses in 4D printing. Virtual and Physical Prototyping. 2015;10:103-22.

Kim DH, Yun WS, Shim JH, Park KH, Choi D, Park MI, et al. Clinical Application of 3-Dimensional Printing Technology for Patients With Nasal Septal Deformities: A Multicenter Study. JAMA otolaryngology-head & neck surgery. 2018;144(12):1145-52.

Kim IG, Park SA, Lee S-H, Choi JS, Cho H, Lee SJ, et al. Transplantation of a 3D-printed tracheal graft combined with iPS cell-derived MSCs and chondrocytes. Scientific Reports. 2020;10(1):4326.

Kim KO, Lee Y, Hwang JW, Kim H, Kim SM, Chang SW, et al. Wound healing properties of a 3-D scaffold comprising soluble silkworm gland hydrolysate and human collagen. Colloids and surfaces B, Biointerfaces. 2014;116:318-26.

King SN, Hanson SE, Hematti P, Thibeault SL. Current applications of mesenchymal stem cells for tissue replacement in otolaryngology-head and neck surgery. Am J Stem Cells. 2012;1(3):225-38.

Kozin ED, Remenschneider AK, Cheng S, Nakajima HH, Lee DJ. Three-Dimensional Printed Prosthesis for Repair of Superior Canal Dehiscence. Otolaryngology-head and neck surgery : official journal of American Academy of Otolaryngology-Head and Neck Surgery . 2015;153(4):616-9.

Kuss MA, Harms R, Wu S, Wang Y, Untrauer JB, Carlson MA, et al. Short-term hypoxic preconditioning promotes prevascularization in 3D bioprinted bone constructs with stromal vascular fraction derived cells. RSC Advances. 2017;7(47):29312-20.

Li T, Chen L, Yuan Y, Shi R. The Current Status, Prospects, and Challenges of Shape Memory Polymers Application in Bone Tissue Engineering. Polymers [Internet]. 2023; 15(3).

Lin Y, Umebayashi M, Abdallah M-N, Dong G, Roskies MG, Zhao YF, et al. Combination of polyetherketoneketone scaffold and human mesenchymal stem cells from temporomandibular joint synovial fluid enhances bone regeneration. Scientific Reports . 2019;9(1):472.

Lu T, Li Y, Chen T. Techniques for fabrication and construction of three-dimensional scaffolds for tissue engineering. International journal of nanomedicine. 2013;8:337-50.

Luo Y, Lin X, Chen B, Wei X. Cell-laden four-dimensional bioprinting using near-infrared-triggered shape-morphing alginate/polydopamine bioinks. Biofabrication . 2019;11(4):045019.

Lyons FG, Al-Munajjed AA, Kieran SM, Toner ME, Murphy CM, Duffy GP, et al. The healing of bony defects by cell-free collagen-based scaffolds compared to stem cell-seeded tissue engineered constructs. Biomaterials . 2010;31(35):9232-43.

McGivern S, Boutouil H, Al-Kharusi G, Little S, Dunne N, Levingstone T. Translational Application of 3D Bioprinting for Cartilage Tissue Engineering. Bioengineering. 2021;8:144.

Mei S, Wang J, Li Z, Ding B, Li S, Chen X, et al. 4D printing of polyamide 1212 based shape memory thermoplastic polyamide elastomers by selective laser sintering. Journal of Manufacturing Processes. 2023;92:157-64.

Mironov V, Boland T, Trusk T, Forgacs G, Markwald RR. Organ printing: computer-aided jet-based 3D tissue engineering. Trends in biotechnology. 2003;21(4):157-61.

Möller T, Amoroso M, Hägg D, Brantsing C, Rotter N, Apelgren P, et al. In Vivo Chondrogenesis in 3D Bioprinted Human Cell-laden Hydrogel Constructs. Plastic and reconstructive surgery Global open. 2017;5(2):e1227.

Moshikur RM, Carrier RL, Moniruzzaman M, Goto M. Recent Advances in Biocompatible Ionic Liquids in Drug Formulation and Delivery. Pharmaceutics [Internet]. 2023;15(4).

Mukherjee P, Cheng K, Flanagan S, Greenberg S. Utility of 3D printed temporal bones in prepre-surgical planning for complex BoneBridge cases. European Arch Oto-Rhino-Laryngol. 2017;274(8):3021-8.

Mulakkal M, Trask R, Ting V, Seddon A. Responsive cellulose-hydrogel composite ink for 4D printing. Materials & Design. 2018;160.

Murphy SV, Atala A. Organ engineering-combining stem cells, biomaterials, and bioreactors to produce bioengineered organs for transplantation. BioEssays : news and reviews in molecular, cellular, and developmental biology. 2013;35(3):163-72.

Nan W, Wang W, Gao H, Liu W. Fabrication of a shape memory hydrogel based on imidazole-zinc ion coordination for potential cell-encapsulating tubular scaffold application. Soft Matter. 2013;9(1):132-7.

Öblom H, Cornett C, Bøtker J, Frokjaer S, Hansen H, Rades T, et al. Data-enriched edible pharmaceuticals (DEEP) of medical cannabis by inkjet printing. International journal of pharmaceutics. 2020;589:119866.

Onerci Altunay Z, Bly JA, Edwards PK, Holmes DR, Hamilton GS, O’Brien EK, et al. Three-dimensional printing of large nasal septal perforations for optimal prosthetic closure. American journal of rhinology & allergy. 2016;30(4):287-93.

Park J-H, Yoon J-K, Lee JB, Shin YM, Lee K-W, Bae S‒W,S-W, et al. Experimental Tracheal Replacement Using 3-dimensional Bioprinted Artificial Trachea with Autologous Epithelial Cells and Chondrocytes. Scientific Reports . 2019;9(1):2103.

Pham DT, Ji C. Design for stereolithography. Proceedings of the Institution of Mechanical Engineers, Part C: Journal of Mechanical Engineering Science. 2000;214(5):635-40.

Pham QP, Sharma U, Mikos AG. Electrospinning of polymeric nanofibers for tissue engineering applications: a review. Tissue engineering. 2006;12(5):1197-211.

Pita-López ML, Fletes-Vargas G, Espinosa-Andrews H, Rodríguez-Rodríguez R. Physically cross-linked chitosan-based hydrogels for tissue engineering applications: A state-of-the-art review. European Polymer Journal. 2021;145:110176.

Potyondy T, Uquillas JA, Tebon PJ, Byambaa B, Hasan A, Tavafoghi M, et al. Recent advances in 3D bioprinting of musculoskeletal tissues. Biofabrication . 2021;13(2).

Ramezani M, Mohd Ripin Z. 4D Printing in Biomedical Engineering: Advancements, Challenges, and Future Directions. J Funct Biomater. [Internet]. 2023;14(7).

Rao F, Yuan Z, Li M, Yu F, Fang X, Jiang B, et al. Expanded 3D nanofibre sponge scaffolds by gas-foaming technique enhance peripheral nerve regeneration. Artif Cells, Nanomed, Biotechnol. 2019;47(1):491-500.

Raucci M, Guarino V, Ambrosio L. Hybrid composite scaffolds prepared by sol-gel method for bone regeneration. Compos Sci Technol. 2010;70:1861-8.

Richard Z, Jackson E, Jung JP, Kanotra SP. Feasibility, and potential of three-dimensional printing in laryngotracheal stenosis. J Laryngol Otol . 2019;133(6):530-4.

Romero RGT, Colton MB, Thomson SL. 3D-Printed Synthetic Vocal Fold Models. J Voice. 2021;35(5):685-94.

Rose AS, Webster CE, Harrysson OL, Formeister EJ, Rawal RB, Iseli CE. PrePre-operative simulation of pediatric mastoid surgery with 3D-printed temporal bone models. International journal of pediatric otorhinolaryngology . 2015;79(5):740-4.

Roseti L, Parisi V, Petretta M, Cavallo C, Desando G, Bartolotti I, et al. Scaffolds for Bone Tissue Engineering: State of the art and new perspectives. Mater Sci Eng C Mater Biol Appl . 2017;78:1246-62.

Roskies MG, Fang D, Abdallah MN, Charbonneau AM, Cohen N, Jordan JO, et al. Three-dimensionally printed polyetherketoneketone scaffolds with mesenchymal stem cells for the reconstruction of critical-sized mandibular defects. The Laryngoscope . 2017;127(11):E392-e8.

Saska S, Pilatti L, Blay A, Shibli JA. Bioresorbable Polymers: Advanced Materials and 4D Printing for Tissue Engineering. Polymers 2021;563. https://doi.org/10.3390/ polym13040563.

» https://doi.org/https://doi.org/10.3390/ polym13040563

Stavrakas M, Karkos PD, Markou K, Grigoriadis N. Platelet-rich plasma in otolaryngology. J laryngol Otol. 2016;130(12):1098-102.

Serna JA, Rueda-Gensini L, Céspedes-Valenzuela DN, Cifuentes J, Cruz JC, Muñoz-Camargo C. Recent Advances on Stimuli-Responsive Hydrogels Based on Tissue-Derived ECMs and Their Components: Towards Improving Functionality for Tissue Engineering and Controlled Drug Delivery. Polymers [Internet]. 2021; 13(19).

Sin D, Miao X, Liu G, Wei FS, Chadwick G, Yan C, et al., editors. Polyurethane (PU) scaffolds prepared by solvent casting/particulate leaching (SCPL) combined with centrifugation. 2010.

Sobczak M. Enzyme-Responsive Hydrogels as Potential Drug Delivery Systems-State of Knowledge and Future Prospects. Int J Mol Sci. [Internet]. 2022; 23(8).

Sultana Phd Ceng Csci N. Mechanical and biological properties of scaffold materials. 2018. p. 1-21.

Tabriz AG, Hermida MA, Leslie NR, Shu W. Three-dimensional bioprinting of complex cell laden alginate hydrogel structures. Biofabrication . 2015;045012. https://doi.org/10.1088/1758-5090/7/4/045012.

» https://doi.org/https://doi.org/10.1088/1758-5090/7/4/045012

Tamay DG, Dursun Usal T, Alagoz AS, Yucel D, Hasirci N, Hasirci V. 3D and 4D Printing of Polymers for Tissue Engineering Applications. Frontiers in Bioengineering and Biotechnology. 2019;1(1);7.

Tibbits S. 4D Printing: Multi-Material Shape Change. Architectural Design. 2014;84(1):116-21.

U. S. F. D. Administration. Technical Considerations for AdditiveManufactured Medical Devices. 2018;1(1):1-31.

Valencia C, Valencia CH, Zuluaga F, Valencia ME, Mina JH, Grande-Tovar CD. Synthesis and Application of Scaffolds of Chitosan-Graphene Oxide by the Freeze-Drying Method for Tissue Regeneration. Molecules [Internet]. 2018;23(10).

Wang Z, Ye Q, Yu S, Akhavan B. Polyethylene Glycol (PEG)-Based Hydrogels for Drug Delivery in Cancer Therapy: A Comprehensive Review. Advanced Healthcare Materials. 2023;12(18):2300105.

Watson J, Hatamleh MM. Complete integration of technology for improved reproduction of auricular prostheses. J Prosthet Dent. 2014;111(5):430-6.

Wei H, Zhang Q, Yao Y, Liu L, Liu Y, Leng J. Direct-Write Fabrication of 4D Active Shape-Changing Structures Based on a Shape Memory Polymer and Its Nanocomposite. ACS applied materials & interfaces. 2017;9(1):876-83.

Wu H, Zhang X, Ma Z, Zhang C, Ai J, Chen P, et al. A Material Combination Concept to Realize 4D Printed Products with Newly Emerging Property/Functionality. Advanced Science. 2020;7(9):1903208.

Xia H, Zhao D, Zhu H, Hua Y, Xiao K, Xu Y, et al. Lyophilized scaffolds fabricated from 3D-printed photocurable natural hydrogel for cartilage regeneration. ACS Appl. Mater Interfaces. 2018;10:31704-31715. 10.1021/acsami.8b10926.

Xu Y, Han J, Chai Y, Yuan S, Lin H, Zhang X. Development of porous chitosan/tripolyphosphate scaffolds with tunable uncross-linking primary amine content for bone tissue engineering. Materials Science & Engineering C, Biomimetic Materials, Sensors, and Systems. 2018;182- 190.

Yang GH, Kim W, Kim J, Kim G. A skeleton muscle model using GelMA-based cell-aligned bioink processed with an electric-field assisted 3D/4D bioprinting. Theranostics. 2021;11(1):48-63.

Yi HG, Choi YJ, Jung JW, Jang J, Song TH, Chae S, et al. Three-dimensional printing of a patient-specific engineered nasal cartilage for augmentative rhinoplasty. J Tissue Eng. 2019;10:2041731418824797.

Yin Z, Li D, Liu Y, Feng S, Yao L, Liang X, et al. Regeneration of elastic cartilage with accurate human-ear shape based on PCL strengthened biodegradable scaffold and expanded microtia chondrocytes. Applied Materials Today. 2020;20:100724.

Zarek M, Mansour N, Shapira S, Cohn D. 4D Printing of Shape Memory-Based Personalized Endoluminal Medical Devices. Macromol Rapid Commun. 2017;38(2):1600628.

Zhang J, Wehrle E, Rubert M, Müller R. 3D Bioprinting of Human Tissues: Biofabrication , Bioinks, and Bioreactors. Int J Mol Sci . [Internet]. 2021;22(8).

Zhang X, Yang Y, Yang Z, Ma R, Aimaijiang M, Xu J, et al. Four-Dimensional Printing and Shape Memory Materials in Bone Tissue Engineering. Int J Mol Sci [Internet]. 2023;24(1).

Zhao Q, Qi HJ, Xie T. Recent progress in shape memory polymer: New behavior, enabling materials, and mechanistic understanding. Prog Polym Sci. 2015;49-50:79-120.

Zhao W, Zhang F, Leng J-s, Liu YJCS. Technology. Personalized 4D printing of bioinspired tracheal scaffold concept based on magnetic stimulated shape memory composites. Compos Sci Technol . 2019.

Zhou G, Jiang H, Yin Z, Liu Y, Zhang Q, Zhang C, et al. In Vitro Regeneration of Patient-specific Ear-shaped Cartilage and Its First Clinical Application for Auricular Reconstruction. EBioMedicine. 2018;28:287-302.

Zhu P, Yang W, Wang R, Gao S, Li B, Li Q. 4D Printing of Complex Structures with a Fast Response Time to Magnetic Stimulus. ACS Appl Mater Interfaces 2018;36435-36442. https://doi.org/10.1021/acsami.8b12853.

» https://doi.org/https://doi.org/10.1021/acsami.8b12853

Zhuo C, Lei L, Yulin Z, Wentao L, Shuangxia W, Chao W, et al. Creation and validation of three-dimensional printed models for basic nasal endoscopic training. International forum of allergy & rhinology . 2019;9(6):695-701.

Zolfagharian A, Denk M, Bodaghi M, Kouzani AZ, Kaynak A. Topology-Optimized 4D Printing of a Soft Actuator. Acta Mech Solid Sin. 2019;33(3):418-30.

Zolfagharian A, Kaynak A, Bodaghi M, Kouzani AZ, Gharaie S, Nahavandi S. Control-Based 4D Printing: Adaptive 4D-Printed Systems. Applied Sciences [Internet]. 2020;10(9).

Zopf DA, Mitsak AG, Flanagan CL, Wheeler M, Green GE, Hollister SJ. Computer aided-designed, 3-dimensionally printed porous tissue bioscaffolds for craniofacial soft tissue reconstruction. Otolaryngol-Head Neck Surg: official journal of American Academy of Otolaryngology-Head and Neck Surgery. 2015;152(1):57-62.

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Published

2025-02-11

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Vol. 61 (2025)

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Review

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Personalized solutions for ENT implants: The role of 3D/4D printing. (2025). Brazilian Journal of Pharmaceutical Sciences, 61. https://doi.org/10.1590/