Digital light processing (DLP)
These technologies and the related advantages enable the researchers to improve existing medical applications that use 3D-printing technology and to explore new ones. The medical goal that has been already reached is significant and exciting, but some of the more revolutionary applications, such as bio/organ printing, require more time to evolve [ 2 ].
Materials used in 3D printing are transformed during the production of the specific model by changing their consistency. This process is named cure and can be done in different ways: a melting of a hard filament in order to give the desired form to the model by the material distortion, liquid solidification for the construction of the structure and powder solidification. All these processes require filler or support material in lattice forms avoiding distortion of the model while the material is being cured. The support material can be easily removed by hand with a cutting tool; however, there is the risk to leave impression on the surface requiring an additional polishing in order to obtain a good-quality printing. The risk of damaging the model, losing details, or break the geometry is really high [ 23 ].
The correct selection of the material is directly linked to the selection of the 3D-printing process and printer, as well as the requirements of the model. Related to medical application, similarly to other applications, different anatomical structures need different mechanical properties of the materials to fulfill the required performance of the printed object [ 8 ]. The main distinction among the different materials that characterize the human body is between rigid and soft materials. Human bones are an example of rigid tissue and ligaments or articular cartilage are examples of soft materials. Bones are the simplest and easiest biological tissue to be produced by 3D printing as the majority of the materials are rigid. The materials used in 3D printing to model the bone structure are for example acrylonitrile butadiene styrene (ABS) [ 23 ], powder of plasters [ 24 ], and hydroquinone [ 8 ].
Relating to soft tissues, deeper research is still needed in order to decrease the gap between a 3D-printed anatomical model and the human structure. Most of the 3D-printing materials present a lack of realism to mimic adequately a soft human biological tissue. Thus, postprocessing may be necessary in order to soften the printed structures. Some examples are given in the reproduction of cartilaginous tissues [ 25 ], arteries for practicing valve replacement [ 26 ], hepatic segment [ 27 ], and hearts [ 28 ]. An interesting example is the development of a 3D-printed brain aneurysm using the flexible TangoPlus™ photopolymer [ 29 ] that represented a useful tool to plan the operative strategy in order to treat congenital heart disease. Furthermore, some of the materials used are urethane and rubber-like material, mixed with a rigid photopolymer, to reasonably mimic the artery structure due to their Shore value and elastic properties similar to the physiological one [ 30 , 31 ].
For a promising future, the multimaterial composites seem to represent a good chance for the 3D printing of human tissues since none of the current available material is able to fully mimic elastic and biological tissues. Multimaterial composites may be designed based on the capacity of the selected biological material to replicate the mechanical properties of human tissue [ 32 ]. Mechanical testing may represent a necessary tool to analyze the biomechanical response and validate the artificial material.
Moreover, it is also important to mention that 3D printing allows the reproduction of implantable custom device, but still deeper research needs to be done in order to examine the differences between the traditional and additive manufacturing in terms of mechanical and structural properties, especially fatigue limit needs to be examined further [ 33 ].
Every year, 3D printing offers more and more applications in the healthcare field helping to save and improve lives in ways never imagined up to now. In fact, the 3D printing has been used in a wide range of healthcare settings including, but not limited to cardiothoracic surgery [ 34 ], cardiology [ 26 ], gastroenterology [ 35 ], neurosurgery [ 36 ], oral and maxillofacial surgery [ 37 ], ophthalmology [ 38 ], otolaryngology [ 39 ], orthopaedic surgery [ 22 ], plastic surgery [ 40 ], podiatry [ 41 ], pulmonology [ 42 ], radiation oncology [ 43 ], transplant surgery [ 44 ], urology [ 45 ], and vascular surgery [ 46 ].
Thanks to the different benefits that this technology could induce in the field, the main direct applications of 3D printing in the medical and clinical field are as follows [ 47 ]:
Therefore, these examples clearly demonstrated that 3D printing is one of the most disruptive technologies that have the potential to change significantly the clinical field, improving medicine and healthcare, making care affordable, accessible, and personalized. As printers evolve, printing biomaterials get safety regulated and the general public acquires a common sense about how 3D printing works.
The biomedical field is one of the areas in which 3D printing has already shown its potentialities and that, in not too distant future, may be one of the key elements for the resolution of important problems related to human health that still exist.
Nowadays, despite the additive manufacturing offers a great potential for the manufacturing, the 3D-printing products do not have a proper legal status that defines them, both for implantable and nonimplantable devices. All the 3D-printed products are categorized as custom-made device under the Regulation (EU) 2017/745 of the European Parliament and of the Council of the 5 April 2017 [ 74 ]. They are defined as follow: “ any device specifically made in accordance with a written prescription of any person authorized by national law by virtue of that person's professional qualifications which gives, under that person's responsibility, specific design characteristics, and is intended for the sole use of a particular patient exclusively to meet their individual conditions and needs ”. Differently for mass-produced devices “ which need to be adapted to meet the specific requirements of any professional user and devices which are mass-produced by means of industrial manufacturing processes in accordance with the written prescriptions of any authorized person shall not be considered to be custom-made devices ” [ 75 ]. Indeed, manufacturers of custom-made devices shall only be guaranteed by an obligation of conformity assessment procedures upon which the device shall be compliant with safety and performance requirements [ 76 ]. Furthermore, the regulation states that “ Devices, other than custom-made or investigational devices, considered to be in conformity with the requirements of this Regulation shall bear the CE marking of conformity ” [ 77 ]. Thus, these medical devices do not require affixation of CE markings: a significant and constraining procedure demonstrating the safety and the performance of the device for the patient. Moreover, the custom-made devices do not require the UDI System (Unique Device Identification system) as reported in the Article 27, Comma 1 of the regulation.
A different approach has to be applied for custom-made implants, such as dental prostheses, that are defined as “ any device, including those that are partially or wholly absorbed, which is intended :
by clinical intervention and which is intended to remain in place after the procedure.
Any device intended to be partially introduced into the human body by clinical intervention and intended to remain in place after the procedure for at least 30 days shall also be deemed to be an implantable .” [ 78 ]. The custom-made implantable devices require the CE marking in order to guarantee the safety and to be commercialized.
The EU has been working for many years on an update to the Medical Devices Directive. This proposed legislation has many noble attributes in addition to overcoming the gaps of the existing Medical Devices Directive, such as supporting technology and science innovation, while simultaneously strengthening patient safety. However, the current version of the draft Regulation lacks some depth that is mandatory to safeguard safe usage of 3D-printing technology and, thus, enable its increasing prevalence in medicine.
Three-dimensional (3D) modelling and printing greatly supports advances in individualized medicine and surgery. Looking to the field of paediatrics, it is possible to identify four main applications categories: surgical planning, prostheses, tissue construct, and drug printing.
There are many successful cases that demonstrate the potential of the additive manufacturing in surgical planning in paediatric cases. In particular, most of the applications of 3D printing reported in the literature are related to the congenital heart disease [ 29 ]. This is due to the fact that children have a smaller chest cavity than adults, and the surgical treatment in paediatric cases may be much more difficult. The additive manufacturing helps the surgeons to have more information than the only ones that imaging technologies can afford. It helps the surgeon in the spatial orientation inside the cavities of a small infant heart and in simulating the surgical approach and steps of the operation with high fidelity [ 79 ]. This leads to shorter intraoperative time that per se has significant impact on complication rate, blood loss, postoperative length-of-stay, and reduced costs [ 80 ]. An example of the application of the 3D printing in the paediatric congenital heart disease treatment is a study reported in the literature based on the development of a 3D heart model of a 15-years-old boy to improve interventional simulation and planning in patient with aortic arch hypoplasia. The 3D-printed model allowed simulation of the stenting intervention. The assessment of optimal stent position, size, and length was found to be useful for the actual intervention in the patient. This represents one of the most technically challenging surgical procedures which opens the door for potential simulation applications of a 3D model in the field of catheterization and cardiovascular interventions [ 81 ].
Another study proposed in which the 3D printing had a relevant role consists in a clinical preoperative evaluation on five patients ranged from 7 months to 11 years of age affected by a double outlet right ventricle with two well-developed ventricles and with a remote ventricular septal defect. The three-dimensional printed model based on the data derived from computed tomography (CT) or magnetic resonance (MRI) contributed to a more complete appreciation of the intracardic anatomy, leading to a successful surgical repair for three of the five patients. [ 82 ] Lastly, CT and MRI data were used to construct 3D digital and anatomical models to plan a heart transplantation surgical procedure of two patients of 2 and 14 years old affected relatively by hypoplastic left heart syndrome and pulmonary atresia with a hypoplastic right ventricle. These physical models allowed the surgeon and the paediatric cardiologist to develop the optimal surgical treatment during the heart transplantation anticipating problems that may arise during the procedure. The specific dimensions and distances can be measured, and heart transplantation can be planned [ 83 ].
The importance of three-dimensional printing has been demonstrating also in other application. The additive manufacturing in fact has been used to plan surgical treatment of paediatric orthopaedic disorders [ 84 ]. The 3D model of a 2-year-old male child was produced in order to plan the surgical treatment for his multisutural craniosynostosis with a history of worsening cranial deformity. Other than the turribrachycephalic skull, the child also had greatly raised intracranial pressure with papilledema and copper beaten appearance of the skull. Thorough preoperative planning enabled faster surgery and decreased anesthesia time in a compromised patient [ 85 ].
Another study, based on 13 cases of multiplane spinal or pelvic deformity, was developed in order to demonstrate that the three-dimensional printing may represent a useful tool in the surgical planning of complex paediatric spinal deformities treatment [ 86 ].
Changing the final goal of the additive manufacturing, other applications cases are reported in the literature to demonstrate the usefulness in the production of paediatric patient-specific prostheses. An example in the literature is given by the development of a low-cost three-dimensional printed prosthetic hand for children with upper-limb reductions using a fitting methodology that can be performed at a distance [ 87 ]. This specific case demonstrates that the advancements in computer-aided design (CAD) programs, additive manufacturing, and imaging editing software offer the possibility of designing, printing, and fitting prosthetic hands devices overcoming the costs limitation. As a consequence, the advantages of 3D-printed implants over conventional ones are in terms of customizability and cost as seems to be clear from the previous example. On the contrary, the major adversity is related to the rapid physical growth that makes the customize prostheses outsized frequently. This leads to the production of advanced technological implant that, due to their high complexity and weight, increases cost. The additive manufacturing can be used to fabricate rugged, light-weight, easily replaceable, and very low-cost prostheses for children [ 88 ]. The major prostheses lack is related to the ability to communicate with the brain in terms of sensibility. With the advent of bioprinting, cellular prostheses could be an interesting area of research, which can lead to integrated prostheses in the brain communication system, and exhibit more biomimicry with tissue and organ functionalities [ 89 ].
Related to bioprinting, there are few applications nowadays involved in the tissues production in regenerative medicine. Many different tissues have been successfully bioprinted as reported in many journal articles [ 90 ] including bone, cartilage, skin, and even heart valves. However, the bioprinted tissues and organs are at the laboratory level; a long way needs to be travelled to achieve successful clinical application [ 91 ].
Last but not the least, the additive manufacturing in terms of drug printing may also represent an innovative technique in the production of patient-specific medicine with regard to the composition and the dose needed by the patients. The drug-printing introduces the concept of tailor-made drugs in order to make drugs safer and more effective. Especially for children, furthermore, drug-printing represents the possibility of choosing colour, shape, and design of the medication, reducing the resistance in taking them. Imagine a paediatrician talking to a four-year-old child who is having trouble adjusting to taking daily doses of steroids after being diagnosed with Duchenne muscular dystrophy the previous month. 3D printing allows us to design in particular shape the drug, making medicine more appealing to the child [ 92 ]. It is amental to note that changing the shape of a capsule does not have to lead to different dose and drug properties, such as drug release or dissolution rate [ 93 ].
The 3D printing in medical field and design needs to think outside the norm for changing the health care. The three main pillars of this new technology are the ability to treat more people where it previously was not feasible, to obtain outcomes for patients and less time required under the direct case of medical specialists. In few words, 3D printing consists in “enabling doctors to treat more patients, without sacrificing results” [ 94 ].
Therefore, like any new technology, 3D printing has introduced many advantages and possibilities in the medical field. Each specific case in which 3D printing has found application shown in this analysis is a demonstration of this. However, it must be accompanied by an updated and current legislation in order to guarantee its correct use.
The publication of the article was funded through the collaboration between Aid4Med S.r.l. and the Universitè Libre de Bruxelles.
The authors declare that there are no conflicts of interest regarding the publication of this paper.
3D printing has opened up a world of possibilities for hobbyists, tinkerers, and creators alike. For beginners, diving into the realm of 3D printing can be both exciting and intimidating. To help ease the transition, we’ve compiled a list of the top 3D printing projects that are not only fun and straightforward but also serve as excellent practice for honing your skills. Additionally, we’ll share recommendations for beginner-friendly filaments and essential tips for achieving successful prints.
A phone stand is a practical and simple project perfect for beginners. With various designs available, you can choose one that fits your style. This project will help you understand basic print settings and support structures. Opt for a design with minimal overhangs to ensure a smooth print.
Tired of tangled cables? Print your own cable organiser! This project is not only useful but also a great way to learn about printing small parts with precision. Look for designs that include slots for different cable sizes and experiment with different filament types to find what works best for you.
Keychains are small, quick, and customisable projects that can add a personal touch to your keys. Start with a simple design and gradually try more intricate patterns as you gain confidence. Keychains also make for excellent gifts.
A small planter is an ideal project for beginners interested in combining their love for gardening with 3D printing. Choose a design that doesn’t require supports, and experiment with different filament colours to match your décor.
Keep your workspace tidy with a 3D printed desk organiser. There are countless designs available, from simple trays to intricate compartmentalised organisers. This project will help you learn about printing larger objects and dealing with potential warping issues.
A pen holder is another practical project that can spruce up your desk. Choose a basic cylindrical design or explore more creative shapes. This project will teach you about the importance of infill density and wall thickness in 3D printing.
For book lovers, 3D printed bookmarks are a fantastic and easy project. Simple flat designs are quick to print and can be customised with your favourite quotes or patterns. This project is perfect for practicing precise layer adhesion.
It goes without saying that puzzles are fun to print and solve. Start with a simple puzzle design to get familiar with assembling multiple parts. As you gain experience, you can try more complex puzzles that will challenge both your printing and problem-solving skills.
Coasters are useful household items that are easy to print. Choose designs that incorporate different textures and patterns to make your coasters both functional and aesthetically pleasing. This project will help you understand surface finishes and layer resolution better.
Printing small toys, such as miniature figurines or simple articulated models, is a delightful project for beginners. These prints can be more complex, allowing you to practice using supports and fine-tuning print settings to achieve detailed results.
Choosing the right filament is crucial for successful 3D printing. For beginners, we recommend starting with PLA (Polylactic Acid) filament due to its ease of use and low printing temperature. PLA is biodegradable, available in various colours, and produces minimal warping.
Another excellent option is PETG 3D printing filament . PETG (Polyethylene Terephthalate Glycol) combines the ease of PLA with the durability of ABS; it’s slightly more challenging to print than PLA but offers better impact resistance and flexibility, making it ideal for functional parts.
Embarking on your 3D printing journey with these beginner-friendly projects will set you on the path to becoming a proficient 3D printing enthusiast. Remember to start with simple designs, gradually take on more complex projects, and enjoy the process of creating tangible objects from digital designs. Happy printing!
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"We are empowering users with faster file preparation for complex designs and enabling more efficient printing of multiple parts in a single build."
by Laura Griffiths
25 June 2024
Materialise
Materialise has launched the latest version of its Magics additive manufacturing (AM) software at RAPID + TCT .
The Belgian 3D printing company says its flagship data and build preparation platform now includes features that improve efficiency and cost-effectiveness for users integrating new parts and designs for AM.
A new Lattice Module that supports beam lattices has been added to help users create complex designs with lighter data sets, for faster, more accurate file processing and preparation. There’s also an enhanced Nester Module, which enables users to automatically place multiple parts onto a build platform and create protective packaging customised to the design of each part. Updates to the Magics user interface have also been added, including a new dark theme option to help reduce visual strain when using the platform for extended periods.
"Materialise remains at the forefront of the 3D printing industry by actively addressing user needs and introducing innovative technology and features that solve their pain points. With this new version of Magics, we are empowering users with faster file preparation for complex designs and enabling more efficient printing of multiple parts in a single build,” said Egwin Bovyn, Magics Product Line Manager at Materialise.
Materialise is also highlighting several new partnerships including its previously announced integration with Ansys ’ simulation software for laser powder bed fusion, and a new collaboration unveiled yesterday with nTop to integrate its implicit modelling API with Materialise Magics 3D Print Suite and NxG Build Processor . Today, EOS is also expanding its existing collaboration with Materialise as its aims to streamline quality control in 3D printing and reduce inspection costs for metal printed parts in the aviation and medical industries.
Materialise will integrate multiple EOS process data sources, including optical tomography (OT) and powder bed camera data, with the AI analytics and correlation capabilities of the Materialise Quality & Process Control (QPC) system. This is said to enable extensive inspection of AM process data to detect anomalies, and eliminate the costly quality review of parts post-manufacturing. As a member of the EOS Developer Network (EDN), Materialise also has access to the different open APIs, which provide data generated during the build process. Materialise’s QPC system, part of Materialise’s CO-AM Software Platform, uses the open EOS interfaces to import OT data generated in EOS systems.
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The freedom created by 3D printing is not limitless though, and whilst Obama refers to 'almost everything' we should take time to understand the true parameters of this technology. Firstly, current 3D printers are bounded by their space envelope. The Replicator 2 can print objects of 28.5 x 15.3 x 15.5 cm.
The concept of 3D printing is an advanced form of the traditional 2D printing done on a surface. 3D printing creates tangible objects and those that can occupy space. This is done by the use of computer aided designs and by applying different types of the design software (Lipson & Kurman 11). Get a custom Essay on 3D Printing Industry and Market.
Currently, 3D printing primarily used for producing artificial heart pump [3], jewelry collections [4], 3D printed cornea [5], PGA rocket engine [6], steel bridge in Amsterdam [7] and other products related to the aviation industry as well as the food industry. 3D printing technology has originated from the layer by layer fabrication technology ...
The use of 3-D printing, also known as additive manufacturing, has moved well beyond prototyping, rapid tooling, trinkets, and toys. Companies such as GE, Lockheed Martin, and BMW are switching to ...
The 3D printing of complex shapes requires high workability for extrusion i.e., extrude-ability or open time, and high early strength of concrete to support subsequent layers i.e., build-ability [140]. A mix design that can satisfy the requirement of prolonged workability before setting for extrusion but at the same time have high early ...
3D printing is a rapidly growing technology that has the potential to revolutionize various industries. From healthcare to manufacturing, 3D printing has a wide range of applications and possibilities. If you are looking for essay topics related to 3D printing, look no further.
3D Printing Industry and Market. One can understand the industry of 3D technologies in terms of the software technology, the hardware and the nature of the products. 3D Printing: Pros and Cons. The authors compare the quick advancement and loss in the price of 3D printers with the rise of the personal computers.
A computer is connected to a 3D printer and the resulting drawings are printed out as models. More ambitious ideas in laboratories came up such as Russians plan to build futuristic moon base using 3D print technology, according to Osborne S. (2019). Effects of 3D Printing. One of the effects of 3D printing is mass-manufacturing declining.
14 essay samples found. 3D Printing, also known as additive manufacturing, is a process of creating three-dimensional objects from a digital file. Essays on 3D printing could explore its evolution, various applications across industries like healthcare, automotive, and aerospace, and its potential to revolutionize manufacturing.
Connection to Microeconomic Theory. One of the main points of the article is that 3D printing allows small businesses and private companies to manufacture parts and products that are virtually identical to those of large companies that would previously hold a monopoly on them (Magliocca & Desai, 2013).
3d Printing Essay Examples. Essay Examples. Essay Topics. graded. The Influence of Advancement in 3d Printing on Society. The process of 3D printing has become a global phenomenon that is commonly practiced all around the world today. From 3D printing prosthetic limbs to guns, people have found a wide variety of uses for the technology.
A. Definition of 3D printing B. Importance of 3D printing in various industries C. Thesis statement: This essay will explore the various applications and benefits of 3D printing technology. II. Overview of 3D Printing Process A. Explanation of additive manufacturing technique B. Brief description of the different types of 3D printing technologies
Advantages Of 3d Printing. 3D printing is a method where three-dimensional physical object's can be created to any shape from a digital model. In the early 19's, 3D printing was an impractical idea that was only a dream. However, in 1980 the first 3D printing technology was invented by Charles Hull and it was called stereo lithography.
The main components of a 3D printer: A 3D printer includ es a set of components that operate simultaneously to produce the desired. output from the input digital file, the basic components of a 3D ...
3D printing also known as additive manufacturing is an old technology that has been referred to as a group of technologies that build physical objects directly from 3D-CAD data file [125].In contrast to subtractive manufacturing technologies (such as milling or machining, cutting, lathing, turning, etc.),... 3D Printing. Graphic Design. Invention.
3D Printing apart from being cost effective is also environment friendly, hence can help to mitigate the adverse effects of industrialization on the environment. Based on the literature studied it can be concluded that a number of 3D printing technologies have evolved having different materials compatible with them. Each 3D printing technology ...
Essays on 3d Printing. Essay examples. Essay topics. 8 essay samples found. Sort & filter. 1 Design of 3d Printable Concrete . 2 pages / 1050 words . Abstract 3D concrete printing is the most revolutionary idea in the field of concrete technology to get a breakthrough instead of diversified constraints. it promises to be highly advantageous in ...
These essays cover a range of topics, from the history and development of 3D printing, to the practical applications of the technology in various industries. They also discuss the potential impact of 3D printing on manufacturing, design, and even medicine. Some essays delve into the legal and ethical considerations surrounding 3D printing, such ...
3D printing has become more affordable and advanced. New 3D printers make 3D printing truly useful. There are already printers that can print with composite materials, ensuring fully functional parts.
We can already see that 3D printing is the future of manufacturing. In 2013 alone, the use of metal 3D printers increases by 75%. Now 3D printing is a billion-dollar industry. Researchers have many great strides in the young field of 3-Dimenstional technology. Just in the last 10 years we've gone from a few companies experimenting to actually ...
Abstract This paper provides a critical review of the related literature on 3D printing in construction. The paper discusses and evaluates the different 3D printing techniques in construction. The paper also discusses and categorizes the benefits, challenges, and risks of 3D printing in construction. The use of 3D printing technology offers several advantages over traditional methods. However ...
A company by the name of Planetary Resources developed a spacecraft in 2014 that was fully made utilizing 3D technology. The craft was designed using CAD software and parts were printed using 3D printers. The final product cost and weighed significantly less than an average NASA satellite. The final product was designed to be rather simple and ...
Creating structures using 3D printing printers requires, first and foremost, 3D model design. A recipe for building materials should be created by determining the proper mixing ratios in order to be able to stack layers on top of one another without collapsing and to carry out 3D printing without shrinkage cracks.
The Benefits of a 3-D printer in construction. 3-D printing makes the construction process faster and more accurate. The advantages are mainly attributed to the fact that the human factor is eliminated in modeling (Husseini para. 3). Since machine production is involved, the element of approximations is resolved, and only exact values are given ...
3D printing is an ingenious concept and a groundbreaking technology that impacts a wide range of disciplines such as architecture, industrial design, manufacturing, and art. Owing to its power to grant users the exceptional capability to quickly and accurately convert a digital design into a 3D physical object, 3D printing gradually caught the ...
The 3D-printing technology allows to provide to the surgeon a physical 3D model of the desired patient anatomy that could be used to accurately plan the surgical approach along with cross-sectional imaging or, alternatively, modelling custom prosthetics (or surgical tool) based on patient-specific anatomy [ 50 - 54 ].
3D printing has opened up a world of possibilities for hobbyists, tinkerers, and creators alike. For beginners, diving into the realm of 3D printing can be both exciting and intimidating. To help ease the transition, we've compiled a list of the top 3D printing projects that are not only fun and straightforward but also serve as excellent ...
3D Organ Printing Essay. The field of bioprinting, using 3D printing technology for producing live cells with extreme accuracy, could be the answer to many of the problems we as humans face in the medical field. It could be the end to organ waiting lists and an alternative for organ transplants. In 3D printing technology lies the potential to ...
Materialise is also highlighting several new partnerships including its previously announced integration with Ansys' simulation software for laser powder bed fusion, and a new collaboration unveiled yesterday with nTop to integrate its implicit modelling API with Materialise Magics 3D Print Suite and NxG Build Processor.Today, EOS is also expanding its existing collaboration with Materialise ...