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Journal articles on the topic 'Implants bio printing prosthetics'

Author: Grafiati
Published: 2 June 2025
Last updated: 31 July 2025

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1

Nitesh, Kurrey* Monika Rakse. "A Review: 3D Printing in Medical Technology." International Journal of Pharmaceutical Sciences 3, no. 5 (2025): 2967–75. https://doi.org/10.5281/zenodo.15453549.

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This article looks at how 3D printing is being used in medicine today. It starts by explaining how and why 3D printing is changing the way doctors work, teach, and do research. Then, it gives some recent examples to show what is currently possible with this technology. Finally, it talks about the limits of 3D printing in medicine and where we might see improvements in the future in recent years, 3D printing has become a powerful tool in healthcare, offering personalized solutions for patients. It allows for the creation of custom implants, prosthetics, and even models of organs that help surge
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Dasharath, R., Yeole Shivraj Narayana, Kode Jaya Prakash, and Narendra Pothula. "Trends in characterization and analysis of TKA implants for 3D printing." E3S Web of Conferences 430 (2023): 01275. http://dx.doi.org/10.1051/e3sconf/202343001275.

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In almost every country, knee joint problems are common among humans. As per American Academy of Orthopedic Surgeons, it is estimated that 3.5 million individuals in the world will undergo knee replacement surgery by 2030. People with advanced rheumatoid arthritis, or long-standing osteoarthritis are usually affected by this deformity due to changes in lifestyle. These conditions mainly affect middle-aged and elderly individuals with osteoarthritis or severe knee injuries. These problems can be overcome with the help of total knee implants by undergoing surgical procedures for providing relaxa
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Azad, Singh*. "AN ANALYSTICAL REVIEW OF METAL 3D PRINTING." INTERNATIONAL JOURNAL OF ENGINEERING SCIENCES & RESEARCH TECHNOLOGY 6, no. 7 (2017): 756–60. https://doi.org/10.5281/zenodo.834487.

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The purpose of this paper is to review the recent trends in the Metal 3D Printing. Metal 3D Printing holds a unique position in modern-day product development. It allows for the direct manufacturing of complex end-use parts and facilitates tooling for conventional manufacturing technologies, reducing costs and lead times.3D printing is a technology on the cusp, and therefore it is essential that you be fully prepared for its arrival. The only way to profit from great changes is to anticipate them in the very early stages and be ready to take advantages of the opportunities that they create. We
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Singh, Shailja, and Manvendra Singh Khatri. "A Review on Orthopaedic Biomaterials: Properties, Advances, and Future Directions." Journal of Condensed Matter 3, no. 02 (2025): 9–16. https://doi.org/10.61343/jcm.v3i02.126.

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Orthopaedic biomaterials play a pivotal role in advancing fracture fixation, joint replacement, and dynamic stabilization within orthopaedic applications. Primarily composed of metals, these biomaterials exhibit outstanding properties including high strength, ductility, fracture toughness, hardness, corrosion resistance, durability, and biocompatibility. Despite their versatility, the landscape of orthopaedic implant materials remains dominated by a limited range of metals, ceramics, composites and polymers. However, the durability of these implants is challenged by biological reactions and ma
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Hu, Mingyu. "Research on the Development and Application of 3D Technology." Applied and Computational Engineering 123, no. 1 (2025): 166–70. https://doi.org/10.54254/2755-2721/2025.19586.

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3D printing, also known as additive manufacturing, is a manufacturing technique that creates three-dimensional objects by adding materials layer by layer. Unlike traditional reduction manufacturing such as cutting and grinding, 3D printing does not require the removal of material from large pieces of material to form the desired shape but rather builds the object by adding material. Although the concept of 3D printing dates back to the 19th century, it began to commercialize in the 21st century, though the technology is still evolving. With its advancements, 3D printing technology has become r
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Pushparaj, Karthika, Balamuralikrishnan Balasubramanian, Manikantan Pappuswamy, et al. "Out of Box Thinking to Tangible Science: A Benchmark History of 3D Bio-Printing in Regenerative Medicine and Tissues Engineering." Life 13, no. 4 (2023): 954. http://dx.doi.org/10.3390/life13040954.

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Advancements and developments in the 3D bioprinting have been promising and have met the needs of organ transplantation. Current improvements in tissue engineering constructs have enhanced their applications in regenerative medicines and other medical fields. The synergistic effects of 3D bioprinting have brought technologies such as tissue engineering, microfluidics, integrated tissue organ printing, in vivo bioprinted tissue implants, artificial intelligence and machine learning approaches together. These have greatly impacted interventions in medical fields, such as medical implants, multi-
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Gabor, Alin, Tiberiu Hosszu, Cristian Zaharia, et al. "3D Printing of a Mandibular Bone Deffect." Materiale Plastice 54, no. 1 (2017): 29–31. http://dx.doi.org/10.37358/mp.17.1.4778.

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The aim of this study was to achieve a polymeric scaffold, ex-vivo, using 3D printing technology and then subjecting it to various tests to check its optimal property. Initially there was selected a lower jaw with a bone defect that would have prevented any treatment based prosthetic implant. The mandible was first scanned using an optical scanner (MAESTRO DENTAL SCANNER MDS400). The scanning parameters using optical scanning system are: 10 micron accuracy, resolution 0.07 mm, 2 rooms with High-Resolution LED structured light, two axes. The scan time of the mandible was 4-5 min. Later the same
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Mirzaali, Mohammad J., Vahid Moosabeiki, Seyed Mohammad Rajaai, Jie Zhou, and Amir A. Zadpoor. "Additive Manufacturing of Biomaterials—Design Principles and Their Implementation." Materials 15, no. 15 (2022): 5457. http://dx.doi.org/10.3390/ma15155457.

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Additive manufacturing (AM, also known as 3D printing) is an advanced manufacturing technique that has enabled progress in the design and fabrication of customised or patient-specific (meta-)biomaterials and biomedical devices (e.g., implants, prosthetics, and orthotics) with complex internal microstructures and tuneable properties. In the past few decades, several design guidelines have been proposed for creating porous lattice structures, particularly for biomedical applications. Meanwhile, the capabilities of AM to fabricate a wide range of biomaterials, including metals and their alloys, p
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Chatzipapas, Konstantinos, Anastasia Nika, and Agathoklis A. Krimpenis. "Introduction of Hybrid Additive Manufacturing for Producing Multi-Material Artificial Organs for Education and In Vitro Testing." Designs 8, no. 3 (2024): 51. http://dx.doi.org/10.3390/designs8030051.

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The evolution of 3D printing has ushered in accessibility and cost-effectiveness, spanning various industries including biomedical engineering, education, and microfluidics. In biomedical engineering, it encompasses bioprinting tissues, producing prosthetics, porous metal orthopedic implants, and facilitating educational models. Hybrid Additive Manufacturing approaches and, more specifically, the integration of Fused Deposition Modeling (FDM) with bio-inkjet printing offers the advantages of improved accuracy, structural support, and controlled geometry, yet challenges persist in cell survival
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Zhong, Youxi. "Integrating Electronics and Biomedical Applications in 3D Printing Current Progress and Future Possibilities." Highlights in Science, Engineering and Technology 76 (December 31, 2023): 308–14. http://dx.doi.org/10.54097/6ncqky02.

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Biomedical three-dimensional(3D) printing has redefined the landscape of medical practice, facilitating the customization of implants, prosthetics, and medical instruments. The use of 3D printing, also known as additive manufacturing, empowers healthcare professionals to create patient-specific medical solutions that align seamlessly with anatomical complexities. Through the deposition of material layer by layer, 3D printing allows for the fabrication of intricately designed structures with precision and reproducibility. The medical field has witnessed a paradigm shift as personalized implants
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Cho, Hyo-Joung, and Min-Shin Kim. "Comparison and Applicability of Facial Prosthetic Ear Manufacturing Cases." Journal of the Korean Society of Cosmetology 28, no. 6 (2022): 1206–15. http://dx.doi.org/10.52660/jksc.2022.28.6.1206.

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As a result of synthesizing the advice of experts in facial prosthetics, customized prosthetics for special cosmetics, and medical device manufacturing and sales experts, work competencies that require '3D printing based on digital work methods' are required. It was confirmed that 'prosthesis production, 3D scanning and modeling, and 3D printing' skills are required for work competency. In order to develop a more realistic aesthetic part, more attention and research are being made on the production of implants, and prosthetic manufacturers are developing materials that can extend the durabilit
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IJRAME, Journal. "Additive Manufacturing in Medical Applications: A Comprehensive Review." International Journal of Research in Aeronautical and Mechanical Engineering 12, no. 6 (2024): 01–05. https://doi.org/10.5281/zenodo.12570529.

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Additive Manufacturing (AM), or 3D printing, is transforming the medical field by enabling the creation of highly customized and complex medical devices and implants. This review examines AM's applications in prosthetics, orthotics, surgical instruments, and bioprinting. AM enhances patient-specific treatments by providing better-fitting prosthetics, tailored surgical instruments, and customized implants, leading to improved clinical outcomes. Additionally, bioprinting offers promising advancements in regenerative medicine and tissue engineering. Despite its benefits, AM faces challenges such
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Bełżek, Aleksandra, Marta Żerebiec, Natalia SaJ, et al. "Advances in 3D Printed Orthotics for Rehabilitation." Wiadomości Lekarskie, no. 3 (March 29, 2025): 539–43. https://doi.org/10.36740/wlek/202602.

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3D printing technology has revolutionized medicine, particularly in orthopedic oncology and rehabilitation, by enabling the creation of customized implants, prostheses, and surgical tools. Its ability to produce complex, patient-specific structures with precise mechanical properties has significantly improved surgical outcomes and treatment effectiveness. Additionally, advancements in digital imaging and computer-aided design/computer-aided manufacturing (CAD/CAM) technologies have streamlined the design and manufacturing process, reducing production time while enhancing comfort and functional
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Kale, Prof Nikhil A. "Research and Development in Biomedical Prosthetics." INTERANTIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT 08, no. 06 (2024): 1–5. http://dx.doi.org/10.55041/ijsrem35585.

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In this report the sole data is based on innovation and development in biomedical prosthetics field. The current technology used for prosthetic includes 3D printing, device implants, digital design tools and more. There are several types of biomedical engineering, such as tissue, genetic, neural and stem cells, as well as chemical and clinical engineering for health care. Many electronic and magnetic method uses sensors in equipment such as Computed Tomography (CT) scans, Magnetic Resonance Imaging (MRI) scans, Electroencephalography (EEG). The notation of the idea is using sensors in body sup
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Jiang, Wei, Haiying Mei, and Shuyan Zhao. "Applications of 3D Bio-Printing in Tissue Engineering and Biomedicine." Journal of Biomedical Nanotechnology 17, no. 6 (2021): 989–1006. http://dx.doi.org/10.1166/jbn.2021.3078.

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In recent years, 3D bio-printing technology has developed rapidly and become an advanced bio-manufacturing technology. At present, 3D bio-printing technology has been explored in the fields of tissue engineering, drug testing and screening, regenerative medicine and clinical disease research and has achieved many research results. Among them, the application of 3D bio-printing technology in tissue engineering has been widely concerned by researchers, and it contributing many breakthroughs in the preparation of tissue engineering scaffolds. In the future, it is possible to print fully functiona
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S, Irfan, Dr R. Sathish Kumar, and Prof Reshma R. "Additive Manufacturing in Biomedical Application." International Journal of Innovative Research in Information Security 10, no. 02 (2024): 119–22. http://dx.doi.org/10.26562/ijiris.2024.v1002.17.

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Additive Manufacturing (AM), commonly known as 3D printing, has revolutionized the field of biomedical applications by offering innovative solutions for personalized and complex structures. This technology enables the fabrication of patient-specific implants, prosthetics, and tissues with enhanced precision and customization. The versatility of additive manufacturing allows the incorporation of biocompatible materials, fostering the development of implants tailored to individual anatomical requirements. Additionally, the rapid prototyping capabilities of 3D printing facilitate the creation of
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Honigmann, Philipp, Neha Sharma, Ralf Schumacher, Jasmine Rueegg, Mathias Haefeli, and Florian Thieringer. "In-Hospital 3D Printed Scaphoid Prosthesis Using Medical-Grade Polyetheretherketone (PEEK) Biomaterial." BioMed Research International 2021 (January 11, 2021): 1–7. http://dx.doi.org/10.1155/2021/1301028.

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Recently, three-dimensional (3D) printing has become increasingly popular in the medical sector for the production of anatomical biomodels, surgical guides, and prosthetics. With the availability of low-cost desktop 3D printers and affordable materials, the in-house or point-of-care manufacturing of biomodels and Class II medical devices has gained considerable attention in personalized medicine. Another projected development in medical 3D printing for personalized treatment is the in-house production of patient-specific implants (PSIs) for partial and total bone replacements made of medical-g
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B., Misan, Bohdan Misan, Igor Nevliudov, and Olena Ruban. "3D PRINTING TECHNOLOGIES IN PHARMACEUTICALS: OPPORTUNITIES AND PROSPECTS." Journal of Natural Sciences and Technologies 3, no. 2 (2024): 323–26. https://doi.org/10.5281/zenodo.14542537.

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In recent years, additive manufacturing, commonly known as 3D printing, has become an increasingly critical tool in the medical field due to its ability to produce unique, patient-specific devices. This technology enhances treatment efficacy by allowing for the customization of medical solutions tailored to individual patient needs. Additionally, 3D printing significantly reduces the time and cost associated with the production of medical devices and components. Specifically, it plays a key role in the development of implants, prosthetics, and personalized medical instruments, thereby positive
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Alabi, Micheal Omotayo. "Big Data, 3D Printing Technology, and Industry of the Future." International Journal of Big Data and Analytics in Healthcare 2, no. 2 (2017): 1–20. http://dx.doi.org/10.4018/ijbdah.2017070101.

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This article describes how 3D printing technology, also referred to as additive manufacturing (AM), is a process of creating a physical object from 3-dimensional digital model layers upon layers. 3D printing technologies have been identified as an emerging technology of the 21st century and are becoming popular around the world with a wide variety of potential application areas such as healthcare, automotive, aerospace, manufacturing, etc. Big Data is a large amount of imprecise data in a variety of formats which is generated from different sources with high-speed. Recently, Big Data and 3D pr
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Jokanović, Vukoman, Božana Čolović, Đorđe Antonijević, Milutin Mićić, and Slavoljub Živković. "Various methods of 3D and Bio-printing." Stomatoloski glasnik Srbije 64, no. 3 (2017): 136–45. http://dx.doi.org/10.1515/sdj-2017-0014.

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Summary There is growing need for synthetic tissue replacement materials designed in a way that mimic complex structure of tissues and organs. Among various methods for fabrication of implants (scaffolds), 3D printing is very powerful technique because it enables creation of scaffolds with complex internal structures and high resolution, based on medical data sets. This method allows fabrication of scaffolds with desired macro- and micro-porosity and fully interconnected pore network. Rapid development of 3D printing technologies has enabled various applications from the creation of anatomical
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Park, Gang-Seok, Seong-Kyun Kim, Seong-Joo Heo, Jai-Young Koak, and Deog-Gyu Seo. "Effects of Printing Parameters on the Fit of Implant-Supported 3D Printing Resin Prosthetics." Materials 12, no. 16 (2019): 2533. http://dx.doi.org/10.3390/ma12162533.

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The purpose of the study was to investigate the influence of 3D printing parameters on fit and internal gap of 3D printed resin dental prosthesis. The dental model was simulated and fabricated for three-unit prostheses with two implants. One hundred prostheses were 3D printed with two-layer thicknesses for five build orientations using a resin (NextDent C&B; 3D systems, Soesterberg, The Netherlands) and ten prostheses were manufactured with a milling resin as control. The prostheses were seated and scanned with micro-CT (computerized tomography). Internal gap volume (IGV) was calculated fr
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Sun, Ye. "Prospects of 3D Printing Technology in Dental Medicine." Journal of Clinical and Nursing Research 8, no. 6 (2024): 398–403. http://dx.doi.org/10.26689/jcnr.v8i6.7639.

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With the continuous advancement of technology, the application of 3D printing technology in the field of dental medicine is becoming increasingly widespread. This article aims to explore the current applications and future potential of 3D printing technology in dental medicine and to analyze its benefits and challenges. It first introduces the current state of 3D printing technology in dental implants, crowns, bridges, orthodontics, and maxillofacial surgery. It then discusses the potential applications of 3D printing technology in oral tissue engineering, drug delivery systems, personalized d
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Lin, Neil, Maryse Gagnon, and Kevin Y. Wu. "The Third Dimension of Eye Care: A Comprehensive Review of 3D Printing in Ophthalmology." Hardware 2, no. 1 (2024): 1–32. http://dx.doi.org/10.3390/hardware2010001.

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Three-dimensional (3D) printing is a process in which materials are added together in a layer-by-layer manner to construct customized products. Many different techniques of 3D printing exist, which vary in materials used, cost, advantages, and drawbacks. Medicine is increasingly benefiting from this transformative technology, and the field of ophthalmology is no exception. The possible 3D printing applications in eyecare are vast and have been explored in the literature, such as 3D-printed ocular prosthetics, orbital implants, educational and anatomical models, as well as surgical planning and
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Chohan, Jasgurpreet Singh, Raman Kumar, Sandeep Singh, Shubham Sharma, and R. A. Ilyas. "A comprehensive review on applications of 3D printing in natural fibers polymer composites for biomedical applications." Functional Composites and Structures 4, no. 3 (2022): 034001. http://dx.doi.org/10.1088/2631-6331/ac8658.

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Abstract Over the past few decades, three-dimensional (3D) printing technologies have surpassed the conventional manufacturing techniques due to their wide applications and advantages. The applications of 3D printing in biomedical field is ever increasing due to improvement in accuracy and surface quality of products. The development of biomedical implants through patient specific data and rapid tooling techniques has revolutionized the research activities. Now-a-days, the metal printers have capability to directly create metal implants using biocompatible metallic alloys. This paper focuses o
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Raheem, Ansheed A., Pearlin Hameed, Ruban Whenish, et al. "A Review on Development of Bio-Inspired Implants Using 3D Printing." Biomimetics 6, no. 4 (2021): 65. http://dx.doi.org/10.3390/biomimetics6040065.

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Biomimetics is an emerging field of science that adapts the working principles from nature to fine-tune the engineering design aspects to mimic biological structure and functions. The application mainly focuses on the development of medical implants for hard and soft tissue replacements. Additive manufacturing or 3D printing is an established processing norm with a superior resolution and control over process parameters than conventional methods and has allowed the incessant amalgamation of biomimetics into material manufacturing, thereby improving the adaptation of biomaterials and implants i
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Esposito, Michelle Marie, Jonathan Robert Glazer, and Sara Turku. "The Use of 3D Printing and Nanotechnologies to Prevent and Inhibit Biofilms on Medical Devices." Hygiene 3, no. 3 (2023): 325–38. http://dx.doi.org/10.3390/hygiene3030024.

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Biofilms remain one of the most pervasive complications of the medical field, representing 50–70% of all nosocomial infections and up to 80% of total microbial infections. Since biofilms contain intricately small matrices, different microenvironments, and accumulations of biodiverse microorganisms of different resistances, these structures end up being difficult to target. As we review in this paper, 3D printing and nanotechnology help overcome these unique challenges of targeting biofilms, especially within the medical field. These technologies bring versatility and more precise control to pe
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Gurin, P., V. Bida, and M. Vasylyev. "3D-printing in orthopedic dentistry (literature review)." SUCHASNA STOMATOLOHIYA 124, no. 1 (2025): 39. https://doi.org/10.33295/1992-576x-2025-1-39.

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Introduction. Dental prosthetics is one of the most important areas of dentistry, and it is related to replacing a lost tooth/tooth with the help of artificial dental devices. To solve the problems of the traditional molding and closed stamping process, 3D printing is currently considered a new candidate for the manufacture of customized dental products, which is attracting more and more attention worldwide. All consumables for 3D printing in dentistry are divided into polymer materials, photopolymer resins, ceramics, and metals. The advantages of 3D- printing include the production of desired
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Satyam, Kumar, and Richa Pandey. "Reverse Engineering in Medical-Bio Modeling and Bioengineering." Advanced Science, Engineering and Medicine 12, no. 11 (2020): 1399–402. http://dx.doi.org/10.1166/asem.2020.2593.

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Reverse Engineering (RE) is a process of redesigning, reassembling and restructuring of an existing part. Though it had been a great use in the development of many new designs, products and concepts, it has now been very much utilized in the design and development of the medical implants, prosthetics, and orthopaedic components and also in the tissue engineering. Re has shown successful results in the field of dentistry wherein doctors are utilizing this for maxillofacial surgery and trauma cases. The geometric modeling of the scanned images can be well termed as Bio modeling which is used in
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Jadav, B. "DO-IT-YOURSELF 3D PRINTING FOR ACETABULAR FRACTURE SURGERY: THE WORKFLOW TEMPLATE." Orthopaedic Proceedings 105-B, SUPP_2 (2023): 32. http://dx.doi.org/10.1302/1358-992x.2023.2.032.

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3D printing techniques have attracted a lot of curiosity in various surgical specialties and the applications of the 3D technology have been explored in many ways including fracture models for education, customized jigs, custom implants, prosthetics etc. Often the 3D printing technology remains underutilized in potential areas due to costs and technological expertise being the perceived barriers.We have applied 3D printing technology for acetabular fracture surgeries with in-house, surgeon made models of mirrored contralateral unaffected acetabulum based on the patients’ trauma CT Scans in 9 p
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Mouser, Vivian H. M., Riccardo Levato, Lawrence J. Bonassar, et al. "Three-Dimensional Bioprinting and Its Potential in the Field of Articular Cartilage Regeneration." CARTILAGE 8, no. 4 (2016): 327–40. http://dx.doi.org/10.1177/1947603516665445.

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Three-dimensional (3D) bioprinting techniques can be used for the fabrication of personalized, regenerative constructs for tissue repair. The current article provides insight into the potential and opportunities of 3D bioprinting for the fabrication of cartilage regenerative constructs. Although 3D printing is already used in the orthopedic clinic, the shift toward 3D bioprinting has not yet occurred. We believe that this shift will provide an important step forward in the field of cartilage regeneration. Three-dimensional bioprinting techniques allow incorporation of cells and biological cues
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Luis, Eric, Houwen Matthew Pan, Swee Leong Sing, Ram Bajpai, Juha Song, and Wai Yee Yeong. "3D Direct Printing of Silicone Meniscus Implant Using a Novel Heat-Cured Extrusion-Based Printer." Polymers 12, no. 5 (2020): 1031. http://dx.doi.org/10.3390/polym12051031.

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The first successful direct 3D printing, or additive manufacturing (AM), of heat-cured silicone meniscal implants, using biocompatible and bio-implantable silicone resins is reported. Silicone implants have conventionally been manufactured by indirect silicone casting and molding methods which are expensive and time-consuming. A novel custom-made heat-curing extrusion-based silicone 3D printer which is capable of directly 3D printing medical silicone implants is introduced. The rheological study of silicone resins and the optimization of critical process parameters are described in detail. The
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Put, V. A., A. A. Dolgalev, D. A. Usatov, et al. "The possibilities of additive technologies for targeted tissue regeneration and implantation in a patient with a mandibular defect. A clinical case." Medical alphabet, no. 30 (January 13, 2024): 51–55. http://dx.doi.org/10.33667/2078-5631-2023-30-51-55.

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After injury or removal of neoplasms, bone, soft tissue scar defects and deformities are formed. Methods of reconstructive bone surgery do not reliably allow to restore defects in full. The main problem is constriction, subsequent atrophy and deformation of soft tissues in the defect area. Dental implant-prosthetic rehabilitation in the area of significant bone defects requires the use of design and prototyping of the final result using computer programs and diagnostic models. The clinical experience of using an individual temporary endoprosthesis, a «tissue expander» made by layer-by-layer sy
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Prasanthi Nori, Lakshmi, and S. S. Manikiran. "An outlook on regulatory aspects of 3D printing in pharmaceutical and medical sectors." Current Trends in Pharmacy and Pharmaceutical Chemistry 4, no. 3 (2022): 98–108. http://dx.doi.org/10.18231/j.ctppc.2022.017.

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Since the time of origin, three-dimensional printing has not only mesmerizing the researchers also health professionals too. Even though the process is exciting, it involves fussy coordination and selection process to get a desirable product. Still the manufactures are in confusion state that to follow which regulations and guidelines to gets an approval for their product of 3d printing. The importance of 3D printing has laid to recognize the best suitable product and ways to prevent its misuse. FDA approved more than 100 3D printed medical devices and it includes Orthopedic, Cranial implants,
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Janhavi, Darunte* Deepali Borade Vanita Deore Nisha Deshmukh Rajendra Surawase. "A Review On 3d Printing Technologies for Drug Delivery in Pharmaceuticals." International Journal of Pharmaceutical Sciences 3, no. 2 (2025): 360–76. https://doi.org/10.5281/zenodo.14823217.

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The application of In the field of pharmaceuticals, the use of 3D printers has been grown dramatically in current time due to its many benefits over conventional pharmaceutical manufacturing methods. In this new world, 3D printing has already demonstrated its promise by demonstrating impressive uses the development of pharmaceutical delivery systems. The formulation  of their own floating medicine delivery device using various 3D printing methods and materials. The purpose of 3D printing the objective is to develop delivery systems customized for each individual person's need. Pharmaceuti
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Kopylov, Maksim, Alexander Stepanov, Samvel Apresyan, and Zaven Avetisyan. "CLINICAL EFFICACY OF A METHOD FOR REPLACING BONE DEFECTS IN THE JAWS WITH THE POSSIBILITY OF TEMPORARY DENTAL PROSTHETICS FOR THE PERIOD OF INTEGRATION OF DENTAL IMPLANTS." Actual problems in dentistry 21, no. 1 (2025): 119–26. https://doi.org/10.18481/2077-7566-2025-21-1-119-126.

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The article is devoted to the clinical testing of the developed protocol of dental implantation surgery, including guided bone regeneration and temporary prostheses, for patients with complete edentulism and atrophy of the alveolar bone. The clinical testing of the proposed prosthetics technology involved 24 patients aged 55 to 72 years with complete absence of teeth and atrophy of the jaw bones. All patients underwent surgery according to the developed protocol. At the same time, 18 patients underwent dental implantation on the lower jaw on the day of surgery for installation of an individual
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Feng, Chen, Ji-ping Zhou, Xiao-dong Xu, Ya-ni Jiang, Hong-can Shi, and Guo-qi Zhao. "Research on 3-D bio-printing molding technology of tissue engineering scaffold by nanocellulose/gelatin hydrogel composite." BioResources 14, no. 4 (2019): 9244–57. http://dx.doi.org/10.15376/biores.14.4.9244-9257.

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In the biomedicine field, three-dimensional (3-D) printing of biomaterials can construct complex 3-D biological structures such as personalized implants, biodegradable tissue scaffolds, artificial organs, etc. Therefore, nanocellulose/gelatin composite hydrogels are often selected as bio-printing materials in the 3-D printing of biological scaffolds. Process parameters of 3-D printed bio-scaffolds were studied in this work because formation accuracy of scaffolds is an important part of the molding process. Firstly, the mixing proportion of nanocellulose and gelatin was explored, and the optimu
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Talekar, P. R. "3D Printing: An Introduction to Its Growing Demand and Applications." International Journal of Advance and Applied Research 6, no. 25 (2025): 78–83. https://doi.org/10.5281/zenodo.15290403.

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The process of additive manufacturing, commonly referred to as 3D printing, has transformed a number of sectors by making it possible to produce intricate structures quickly and affordably. A short introduction of 3D printing is given in this paper, emphasizing its wide range of uses and rising demand. This technology's capacity to produce specialized, lightweight, and effective designs in industries like everyday goods, manufacturing, medical equipment, and transportation it is that is driving its growing usage. Prosthetics, bioprinting, and tailored implants are among the medical application
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Wheatley, M. J., and Y. De Deene. "Loss and reintroduction of the radical initiator into the FlexyDos3D silicone dosimeter for 3D printing." Journal of Physics: Conference Series 2630, no. 1 (2023): 012027. http://dx.doi.org/10.1088/1742-6596/2630/1/012027.

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Abstract 3D printers allow for the rapid construction of complex 3D objects that would be very time-consuming with traditional casting techniques. Patient-specific objects have been created for years in the fields of dentistry, prosthetics, and surgical guides. However, 3D printed objects using materials that also serve a functional purpose, biologically or chemically, are now finding bio-medical applications. A custom 3D printer has been made that is able to print the FlexyDos3D silicone dosimeter, but the dosimeter’s sensitivity is severely decreased after printing. Testing was performed to
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Rathod, Vijaysing Thau, and Dr B. N. Sontakke. "Applications of PolyJet 3D Printing in Biomedical and Industrial Engineering." INTERNATIONAL JOURNAL OF SCIENTIFIC RESEARCH IN ENGINEERING AND MANAGEMENT 09, no. 07 (2025): 1–9. https://doi.org/10.55041/ijsrem51296.

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PolyJet 3D printing technology has emerged as a versatile additive manufacturing process that enables high-resolution, multi-material fabrication with applications in both biomedical and industrial engineering. This study explores the capabilities of PolyJet 3D printing, highlighting its role in producing customized prosthetics, bio-models, and surgical tools in the biomedical field, as well as functional prototypes, tooling, and composite parts in industrial applications. The ability to print intricate geometries with a wide range of digital materials, including biocompatible resins and high-
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Mina, Mina, Ajay Kumar Goel, Fady Mina, Doris Goubran, and Nand Goel. "Three-Dimensional Printing for Accessible and Personalized Ophthalmic Care: A Review." Journal of Clinical & Translational Ophthalmology 3, no. 2 (2025): 6. https://doi.org/10.3390/jcto3020006.

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Over 2.2 billion people across the globe face significant barriers to accessing essential ophthalmic care, with elderly, rural, and refugee populations being disproportionately affected, deepening existing disparities in eye care. Three-dimensional printing is a novel technology that has the potential to transform the field and improve access by alleviating many patient-specific barriers. This article delves into the evolution of 3D printing within ophthalmology, highlighting its current applications and future potential. It explores various 3D printing techniques and numerous biomaterials dis
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Raheja, Dev. "System Safety in Healthcare." Journal of System Safety 53, no. 1 (2017): 12–14. http://dx.doi.org/10.56094/jss.v53i1.98.

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A new technology, three-dimensional (3D) printing, has the potential to change the medical world. Objects are made by fusing or depositing materials, such as plastic, metal, powders, liquids or living cells, in layers to produce a 3D object. This technology started in manufacturing and was used to create spare parts for airplanes, eliminating the need for constructing manufacturing prototypes and producing new components within hours instead of weeks.
 The application of this technology in healthcare is growing. It is now used in the creation of customized prosthetics, implants and anatom
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Tichá, Daniela, Juraj Tomášik, Ľubica Oravcová, and Andrej Thurzo. "Three-Dimensionally-Printed Polymer and Composite Materials for Dental Applications with Focus on Orthodontics." Polymers 16, no. 22 (2024): 3151. http://dx.doi.org/10.3390/polym16223151.

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Three-dimensional printing has transformed dentistry by enabling the production of customized dental restorations, aligners, surgical guides, and implants. A variety of polymers and composites are used, each with distinct properties. This review explores materials used in 3D printing for dental applications, focusing on trends identified through a literature search in PubMed, Scopus, and the Web of Science. The most studied areas include 3D-printed crowns, bridges, removable prostheses, surgical guides, and aligners. The development of new materials is still ongoing and also holds great promis
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Petcu, Eugen Bogdan. "3D Bio-Printing: an Introduction to a New Approach for Cancer Patients at the Interface of Art and Medicine." Leonardo 50, no. 2 (2017): 195–96. http://dx.doi.org/10.1162/leon_a_01418.

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Cancer patients require a complex multidisciplinary therapy. In this context the 3D additive biological manufacturing could represent a significant development with potential significant medical and social consequences. This article reviews the 3D bioprinting methods and clinical settings in which this new revolutionary method could be applied. Apart from the actual field of post-cancer therapy prosthetics and medical education, this method could be applied in the actual molecular cancer research and organ regeneration/fabrication. Considering all of these, it is possible that in the future, 3
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Horta-Martínez, Lázaro Ernesto. "3D printing in the medical field." Seminars in Medical Writing and Education 1 (August 31, 2022): 8. http://dx.doi.org/10.56294/mw20228.

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Introduction: 3D printing has represented a technological advance in the field of health sciences. This additive manufacturing allows the creation of grafts, autotransplates and tissue regeneration.Objective: describe the contribution of 3D printing to the field of medicine.Methods: A review of the literature was carried out in the month of November 2023 through access to the databases Scopus, PubMed, Dialnet, Scielo, and the search engine Google Scholar version 2022, with the strategies: ((print 3D) AND (medicine)), ((medicine) AND (technological advances)) and ((3D printing) AND (surgical sc
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Xia, Chenshu. "The present status of research and related applications of three-dimensional printing in the field of healthcare." Applied and Computational Engineering 117, no. 1 (2025): 34–43. https://doi.org/10.54254/2755-2721/2025.19957.

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As a new manufacturing technology, 3D printing technology has shown great potential in healthcare. The current study attempts to provide a comprehensive review of the current research landscape regarding the utilization of 3D printing technology in the healthcare sector. Nowadays, three-dimensional printing is applied in tissue engineering to manufacture complex and functionalized tissue scaffolds, hence providing strong support for regenerative medicine and enabling more precise tissue replacement in vivo. In the context of the manufacturing of medical models, the technology can reproduce wit
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Rezaie, Fereshte, Masoud Farshbaf, Mohammad Dahri, et al. "3D Printing of Dental Prostheses: Current and Emerging Applications." Journal of Composites Science 7, no. 2 (2023): 80. http://dx.doi.org/10.3390/jcs7020080.

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Revolutionary fabrication technologies such as three-dimensional (3D) printing to develop dental structures are expected to replace traditional methods due to their ability to establish constructs with the required mechanical properties and detailed structures. Three-dimensional printing, as an additive manufacturing approach, has the potential to rapidly fabricate complex dental prostheses by employing a bottom-up strategy in a layer-by-layer fashion. This new technology allows dentists to extend their degree of freedom in selecting, creating, and performing the required treatments. Three-dim
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Nathapat, Thongdee. "What is 3D printing and how can it apply in the medical field?" International Journal of Healthcare Sciences 11, no. 1 (2023): 303–6. https://doi.org/10.5281/zenodo.8378928.

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<strong>Abstract:</strong> Three-dimensional (3D) printing, also known as additive manufacturing, has emerged as a transformative technology with significant implications across various industries. In the medical field, 3D printing has gained immense attention for its potential to revolutionize patient care, medical device manufacturing, and pharmaceutical research. This literature review aims to provide a comprehensive overview of what 3D printing is, its historical development, and its applications in the medical domain. This research explores the diverse areas within medicine where 3D print
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Michelutti, Luca, Alessandro Tel, Massimo Robiony, et al. "Progress in 3D Printing Applications for the Management of Orbital Disorders: A Systematic Review." Bioengineering 11, no. 12 (2024): 1238. https://doi.org/10.3390/bioengineering11121238.

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Introduction: 3D printing technology has gained considerable interest in the domain of orbital illnesses owing to its capacity to transform diagnosis, surgery planning, and treatment. This systematic review seeks to deliver a thorough examination of the contemporary applications of 3D printing in the treatment of ocular problems, encompassing tumors, injuries, and congenital defects. This systematic review of recent studies has examined the application of patient-specific 3D-printed models for preoperative planning, personalized implants, and prosthetics. Methods: This systematic review was co
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Kumar, Singh Amit, and Jain Tushar. "Review of 3D Printing Applications in Biomedical Engineering: A Comprehensive Analysis." Journal of Clinical and Biomedical Sciences 14, no. 4 (2024): 129–37. https://doi.org/10.58739/jcbs/v14i4.110.

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Three-dimensional printing (3DP), also known as additive manufacturing, has significantly impacted the biomedical field by enabling the creation of complex, patient-specific medical devices, implants, and tissues. The need for advanced medical solutions due to an aging population and increased reliance on electronic gadgets has driven research into 3DP application. This review focuses on the various biomedical applications of 3DP, including drug synthesis, medical device fabrication, bioprinting, and surgical planning. The review discusses key techniques such as bioprinting, which combines cel
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Dantas, Leticia Ramos, Gabriel Burato Ortis, Paula Hansen Suss, and Felipe Francisco Tuon. "Advances in Regenerative and Reconstructive Medicine in the Prevention and Treatment of Bone Infections." Biology 13, no. 8 (2024): 605. http://dx.doi.org/10.3390/biology13080605.

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Reconstructive and regenerative medicine are critical disciplines dedicated to restoring tissues and organs affected by injury, disease, or congenital anomalies. These fields rely on biomaterials like synthetic polymers, metals, ceramics, and biological tissues to create substitutes that integrate seamlessly with the body. Personalized implants and prosthetics, designed using advanced imaging and computer-assisted techniques, ensure optimal functionality and fit. Regenerative medicine focuses on stimulating natural healing mechanisms through cellular therapies and biomaterial scaffolds, enhanc
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