Dental 3D Printing Solutions

Dental 3D printing is adopted for many applications, including the production of physical models for orthodontics, prosthodontics, and surgery; manufacturing dental implants; construction of drill guides for dental implants; and the fabrication/customization of frameworks for implants and dental restoration.

Best Dental 3D Printing Solutions 2021

1. STRATASYS LTD
2. ROLAND DG
3. 3D SYSTEMS
4. ENVISIONTEC GMBH
5. SLM SOLUTIONS GROUP AG
6. ASIGA
7. RAPID SHAPE
8. FORMLABS
9. CARBON INC
10. Dental Solutions Israel

Market Overview

Dental 3D printers feature lights or lasers that polymerize a liquid or fuse a powder with computer-guided precision, which is required to produce small dental objects in intricate detail. Dental 3D printers produce dental models, parts, and even complete restorations out of a range of suitable materials. Best Dental 3D printing solutions are adopted to produce physical models for orthodontics, prosthodontics, and surgery; manufacture dental implants; construct drill guides for dental implants; and fabricate/customize frameworks for implants and dental restoration. Dental 3D printing reduces inventories, limits material wastage, and provides dental professionals access to innovative designs. 3D dental printing also offers advantages such as reduced product development time for dental appliances, superior-quality complex parts and products, and mass personalization.

The dental 3D printing market is projected to reach USD 6.52 billion by 2025 from USD 1.83 billion in 2020, at a CAGR of 28.8%. The dental 3D printing medical devices market is primarily driven by factors such as the high incidence of dental caries and other dental diseases, rising demand for cosmetic dentistry, the growing adoption of dental 3D printers in hospitals and clinics, and rapid growth in the geriatric population. On the other hand, the rising number of large dental practices is expected to limit market growth to a certain extent.

Based on products & services, the Best Dental 3D printing solutions market is segmented into equipment, materials, and services. The services segment accounted for 65.5% of the dental 3D printing market in 2019. The large share of this segment can be attributed to the competitive pricing offered by dental 3D printing service providers and the large-scale outsourcing of dental product design and production by small hospitals, dental clinics, and laboratories.

The competitive leadership mapping showcased provides information for the best Dental 3D Printing solutions. The vendors are evaluated on two different parameters: Product Offerings and Business Strategy.

This category of best Dental 3D Printing solutions includes Stratasys, Roland, 3D Systems, Envisiontec, and SLM Solutions.

This category of Dental 3D Printing solutions includes Prodways Group, Asiga, Carbon, Rapid Shape, Dentsply Sirona, Renishaw, and Formlabs.

This category of Best Dental 3D Printing solutions includes Keystone Industries, Trumpf Group, Detax, 3BFab, EOS, Voco, 3DResyns, Zortrax, DMG America, Sprintray, and Dental Solutions Israel.

This category of Dental 3D Printing solutions includes DWS Systems, and Concept Laser.

DRIVERS

Dental caries and other dental diseases are common

Dental caries, also known as tooth decay, affects people of all ages, and the global incidence of decayed and missing teeth (DMT) has risen sharply in recent years. According to the CDC, 64.9 percent of adults over the age of 18 had a dental examination or cleaning procedure in 2019. More than 36 million Americans are fully edentulous, according to the American College of Prosthodontists, and about 120 million Americans are missing at least one tooth. The high incidence of target diseases will play a key role in the growth of the Best dental 3D printing solutions market during the forecast period, as dental implants, dental prosthetics, and other dental products produced by dental 3D printers are widely used in the reconstruction of the dental structure.

Rising demand for cosmetic dentistry and preventive dental care

With increasing disposable incomes, the willingness to undergo expensive cosmetic procedures has also risen, specifically among the aging population. Globally, there is a growing demand for dental restoration solutions and aesthetic treatments such as whitening and polishing. Moreover, there has been an increase in the demand for preventive dental care and adoption of cosmetic dentistry in both developing as well as developed countries primarily due to changing lifestyles and a growing focus on dental aesthetics—which is where dental 3D scanners and printers come into play.

Growth in the senior population

Edentulism (tooth loss) is a major oral health concern among the elderly; according to the WHO, ~30% of individuals aged 65 years and above are edentulous. As the elderly are more susceptible to various health conditions, including several dental ailments, this trend is expected to increase the number of people suffering from oral health problems, including edentulism. Periodontal diseases and dental cavities are also major causes of tooth loss.

Rapidity, accuracy, and less labor-intensive process in dental 3D printing

The greatest advantages of dental 3D printing are the speed and accuracy offered by dental 3D printers. An increased level of automation ensures better overall accuracy and far less time consumed than manual model making. Multiple appliances can be printed simultaneously once the digital copy has been sent. This implies that the technician can begin working as soon as the copy of the scan arrives. It also enables dental technicians to have a clean workspace without needing to deal with plaster or inhale grinding dust. Moreover, the availability of Best dental 3D printing solutions indicates that dentists can reduce stored model inventory, with all 3D models being saved in the digital space. These advantages translate to better clinical workflows and an improved treatment experience for patients. For instance, 3D printers can create models for patients prior to surgery, allowing them to visualize the procedure and result, thereby increasing overall patient compliance and acceptance. The incorporation of 3D printing also reduces the number of processes and is overall less invasive, with end products that are functionally and aesthetically more pleasing for patients.

RESTRAINTS

Owing to a lack of advanced training in additive manufacturing, there is a shortage of qualified workers.

The lack of a professional workforce is one of the most significant obstacles to the implementation of additive manufacturing or 3D printing. There is a very small pool of workers who are familiar with 3D printing methods, which is exacerbated by the rapid speed of technological and material evolution in the dental 3D printing industry. There are few training programs available for additive manufacturing, and there is a significant distance between academia and industry implementations that is difficult to cross. The absence of a well-trained workforce would stifle overall adoption.

OPPORTUNITIES

The adoption of CAD/CAM technology is growing

The dental industry is rapidly adopting computer-aided design (CAD)/computer-aided manufacturing (CAM) due to its high accuracy in dental implant. Not only is this technique used to design and produce milled crowns and bridges, but it is often used to design manufactured abutments for dental implants. CAD/CAM is extremely useful for customising dental prosthetics, such as zirconium crowns. Through use of CAD/CAM also decreases the number of doctor visits and the need to wear temporary bridges/crowns during care, lowering the cost of dental reconstruction.

Advancements in resins used for dental 3D printing

Dental 3D printing materials are resins specifically designed and manufactured to produce final-placement dental appliances and functional dental models. Dental model resins have many applications such as education, restorative fitment tests, patient consultation, and fabrication of clear aligners. The variety of applications of dental resins are now being supported by advancements in these materials, which have been classified by FDA as Class Ia and Class IIa biocompatible. These new resins have physical attributes that deem them ideal for applications in dentistry. For instance, in June 2020, Formlabs (US) launched Dental LT Clear V2, Custom Tray Resin, and Temporary CB Resin for application in 3D printing. The Custom Tray Resin material allows a dental impression tray to be produced in the dental clinic in less than an hour, improving clinical workflow and reducing turnaround time. Temporary CB Resin can be used for directly printing temporary dental crowns and other dental appliances that could last up to a year in patients.

These ongoing advancements in resins expand the versatility of application in Best dental 3D printing solutions and indicate an opportunity in this market.

CHALLENGES

Operational expenses and capital spending are also high

Owing to financial limitations, dental 3D printing facilities can be unaffordable for small and medium-sized laboratories. This is a significant problem in the industry since the majority of dental laboratories are small or medium-sized. A high-resolution 3D printer costs between USD 40,000 and USD 100,000. This also makes it impossible for laboratories that rely on federal funding (which is a time-consuming process in and of itself) to build and use such equipment. Many smaller dental clinics may prefer to outsource production to service bureaus or laboratories because of this financial consideration. However, the speed offered by 3D printing reduces considerably in this case as lead time increases, with parts taking days or weeks to be completed.

Moreover, 3D printing is a new technology in the medical field, and health insurance companies usually do not cover costs related to 3D printing surgeries. 3D printing software used during surgeries is very expensive and requires significant collaboration between the radiology and surgical departments for effective functioning. In addition, 3D printing materials cost more than traditionally used materials—the polymer used for Best dental 3D printing solutions are costlier than polymers used in injection molding. As a result, the overall disadvantages and costs outweigh the general usefulness of 3D printing for small and medium-sized end users, whereas bigger and hospital-based laboratories, due to mass production, can bear prices and fully benefit from 3D printers.

The rising number of large dental practices

The number of large dental practices is growing in developed markets across North America and Europe. As per the American Dental Association, as of 2019, there are 200,419 dentists practicing in the US. Over the years, the trend has been shifting towards large corporate practice set-ups instead of traditional solo practices. The reasons for this increasing consolidation include a better work-life balance in large practices, the rising costs of investing in a solo dental practice, and increased concentration of commercial dental insurance.

INDUSTRY TRENDS

ADVANCED 3D PRINTING MATERIALS FOR DENTAL APPLICATIONS

In the field of 3D printing, there is constant innovation to develop unique, new materials that can be utilized in the field of medicine and dentistry. For instance, in May 2020, materials supplier and specialty chemicals company Evonik (Germany) launched a 3D-printable implant-grade polyether ether ketone (PEEK) filament for medical and dental applications. This material allows custom-made implants to be 3D-printed. This high-performance material could be used in Fused Filament Fabrication (FFF) Technology 3D printers for PEEK materials. This material is ideal for use in dentistry for maxillofacial surgery. Similarly, Evonik has also developed RESOMER PrintPowder for 3D-printing complex bioresorbable medical devices.

RISING ADOPTION OF DIGITAL DENTISTRY

The digitization of dentistry has advanced immensely over the years, with the intention of improving the clinical workflow through the incorporation of technology. The industry is experiencing a shift from traditional to digital dentistry. The over-reliance of dentistry on specialized human labor and issues relating to quality, repeatability, and accuracy have fueled this shift significantly. Nearly one-third of all dental laboratories currently own digital scanners and 3D printers. The adoption of new digital dentistry equipment and software is increasing, as digital dentistry is proving to be a cost-effective and beneficial technology for both dental offices and dental laboratories compared to traditional dental treatment methods.

CONSOLIDATION OF DENTAL LABORATORIES

Over the years, the dental industry has been largely fragmented, composed of various small and independent business players. However, in recent years, the rapid adoption of automated production technologies, penetration of 3D printing technology, a growing number of industry regulations, and globalization are causing structural changes in this industry.

Dental laboratories are currently facing various challenges such as high labor costs and undersupply of experienced staff as well as the requirement of significant capital investment for setting up well-equipped and technologically advanced product manufacturing. To address these challenges, small dental laboratories are focusing on collaborating with better-equipped laboratories. Such agreements and acquisitions also benefit large laboratories by expanding their customer reach and foothold. For instance, in October 2018, GDC Holdings, Inc. (US), which owns National Dentex Labs (NDX), acquired Trident Dental Laboratories (US). This acquisition combined the offerings of both clinics to provide superior restorative dentistry options and further advance NDX’s leadership in the dental laboratory industry.

DENTAL 3D PRINTING MARKET, BY PRODUCT & SERVICE

SERVICES

COST-EFFECTIVENESS BOOSTS THE GROWTH OF THE SERVICES SECTOR

Dental 3D printing services include tooling and part production, rapid prototyping, software services, system maintenance, and expert services for training programs.

With advancements in printing technology and materials, the 3D printing services sector is gaining significant traction. As 3D printing facilitates the easy manufacturing of products with complex geometries and offers competitive pricing compared to traditional manufacturing methods, companies across several industries outsource every aspect of the process, from design to production. The same is expected to happen with the dental industry, where small hospitals, clinics, and laboratories will outsource the manufacturing of dental implants, crowns and bridges, and dentures.

MATERIALS

The availability of a wide variety of materials for dental 3D printing has resulted in a shift in focus from rapid prototyping to 3D printing. Materials used to print dental 3D parts mainly comprise plastics and biocompatible resins, polymers, metals and metal alloys, ceramics, and other biomaterials. Metals and plastics are the most widely used raw materials for dental 3D printing. Dental resins are designed and manufactured specifically to produce and place final appliances and functional dental models.

PLASTICS

Plastic is the most common and widely used raw material in dental 3D printing because of its affordability and variety. This segment includes thermoplastic resins, photopolymer resins, SLA (liquid polymer), SLS (polymer powder), and FDM (polymer filament). Biocompatible resins and castable resins are highly preferred for printing crowns, bridges, orthodontic models, splints, retainers, and aligners.

Thermoplastic materials form homogenized liquids when heated and harden when cooled. The ergonomic pliability of thermoplastics makes them ideal for manufacturing prosthetics and surgical instruments. These plastics are soft enough to be comfortable against the human skin and can be hardened and made to withstand repeated and rough use. Acrylonitrile butadiene styrene (ABS), polyurethane, polypropylene (PP), and polyether ether ketone (PEEK) are some examples of 3D printing plastics. While PEEK, PEKK, or ULTEM are high-performance 3D printing plastics with very high mechanical and thermal resistance, they are much lighter than other metals. These properties make these plastics suitable for medical and dental applications.

METALS

Over the years, the use of metal and metal alloy powders in dental 3D printing has increased significantly. The powder is heated and fused with an Yb-fiber laser, which welds the design layer by layer into the powder. Metal 3D printing builds designs in a singular part, eliminating the need for welding and machining multiple units. Products made from metal powders showcase better mechanical strength and surface finish. Moreover, metal dental appliances require less post-processing procedures, thus lessening labor, time, and costs and thereby improving the productivity and quality of the product. However, accuracy and affordability concerns associated with metals are expected to hamper the adoption of these materials in the Best dental 3D printing solutions market.

OTHER MATERIALS

Other materials used in the dental 3D printing market include liquid resins, biomaterials, ceramics, and wax.

Dental-grade liquid resins used in different applications have relevantly suitable properties. The applications of dental-grade resins include the preparation of consultative and visual dental models, the production of clear aligners, and other functional appliances. The development of advanced liquid resins is stimulating the demand for this material.

EQUIPMENT

The growth of this market is majorly due to the increasing adoption of 3D scanners by dentists owing to their better imaging capabilities as compared to traditional spherical scanners and 2D imaging systems.

DENTAL 3D SCANNERS

Dental 3D scanners use lasers and a structured light source to scan an object from many angles and reproduce the image using software. This equipment is often installed with CAD (computer-aided design) and CAM (computer-aided manufacturing) software. Dental 3D lab scanners accurately scan analog impressions sent to the lab by a dentist. This eliminates the need for labs to pour or create a gypsum model from the impression. The refined workflow allows the lab to print economical 3D dental models derived from the analog impression.

DENTAL 3D PRINTERS

A dental 3D printer is used to print a 3D object (including crowns, bridges, and implants) from a digital model. Dental 3D printing follows a unique process of adding materials in successive layers. These printers generate concept models, precision and functional prototypes, and master patterns and molds for tooling.

3D printing was originally not widely applied in dentistry, owing to the high complexities and costs associated with these products, making them affordable only for large laboratories or manufacturers. With technological advancements and cost reductions, the use of 3D printers in the dental industry has increased. Moreover, the physical and visual information and documentation of patients’ anatomy provided by dental 3D printers indicate the huge potential to change the overall process in academic institutes and the successful placement of implants in the dental field.

Another major trend in this industry is the rising expenditure in the research of dental 3D bioprinters. These printers are used to deposit living cells in combination with biologically relevant substances like collagen, fibrin, and gelatin. Dental 3D bioprinters enable the printing of biological tissues in dental surgeries. Currently, no dental 3D bioprinters are available in the market for commercial purposes.

DENTAL 3D PRINTING MARKET, BY TECHNOLOGY

VAT PHOTOPOLYMERIZATION

According to the ISO/ASTM 52900:215, vat photopolymerization (VP) is an additive manufacturing process in which liquid photopolymer in a vat is selectively cured by light-activated photopolymerization. Through this liquid material, vat photopolymerization allows for micrometric layer or even layer-less continuous manufacturing. The light used for this process can be visible or ultraviolet light, depending on the type of resin used.

In the dental industry, photopolymerization is mainly used for manufacturing surgical & dental implants, dentures, CMF (craniomaxillofacial) guides, prosthetics and implants, porous scaffolds, and dental restorations. Photopolymerization is one of the most precise and accurate techniques of dental 3D printing. Moreover, vat photopolymerization is characterized as having the best resolution and surface finish among 3D printing technologies. However, its application is hindered by the limited range of available photopolymeric materials and the high temperatures involved in processing, leading to the thermal degradation of materials. Moreover, the resin-based fabrication methods used in these techniques require time, energy, and equipment and cleaning agents to finalize the end-product.

STEREOLITHOGRAPHY

In SLA, thin layers of resin are built up to create a computer-designed shape. The liquid resin is contained in a tank, and a light-emitting diode or laser energy is used to form individual layers that can be stacked to create objects. A modified and technologically advanced top-down SLA approach has been introduced in the market where the build platform is dipped into the resin from above. This new approach offers several advantages, such as low material requirement over traditional methods. The materials used in stereolithography must be photocurable, like acrylics and epoxies. The dynamics involved in the procedure itself affect the polymerization time and the thickness of the layer cured. The addition of UV can control the depth of polymerization to some extent. Stereolithography is commonly used for making dental implant guides and surgical stents.

DIGITAL LIGHT PROCESSING

DLP uses selective light modulation for manufacturing 3D products. While stereolithography and DLP use an identical chemical process, the light sources used for both differ. The materials used in this technique include a vat of liquid photosensitive resins that harden under visible light conditions followed by UV light for curing the layers. Instead of a laser beam, DLP uses a digital projector to cure the resin and flash a single image of each layer. This technology was first used for 3D printing by EnvisionTEC GmbH (Germany) to produce dental and hearing aid devices.

The disadvantage of DLP printing is that, since it uses a light source, the entire layer is printed in one go, distributing the pixels of light. This results in the low output quality of the outer surface due to the number of units to be printed in a single tray compared to SLA printers.

FUSED DEPOSITION MODELING

Fused deposition modeling (FDM), also known as fused filament fabrication, is a droplet deposition or extrusion-based technology for 3D printing. It is a rapid prototyping and additive 3D printing manufacturing technology that builds products in a layer-wise manner using thermoplastics as raw materials. In this method, the motion of the material is computer-controlled, and the material is deposited in an extremely thin layer onto a subsidiary platform. The materials used with this technology include polymers and plastic materials. Most low-cost dental 3D printers use FDM. In the 1990s, this technique was patented and commercialized for 3D printers by Stratasys. In dentistry, FDM is a widely applied technology due to the availability of a wide range of biocompatible, strong, and sterilizable thermoplastics.

The ability of the FDM machine to use several materials simultaneously makes it useful for printing removable dentures and prosthetics. Low machine and material prices also support their adoption. However, FDM is less accurate than vat photopolymerization and comes with the chance of causing warping in zirconia and cast metal frameworks.

SELECTIVE LASER SINTERING

HIGH PRODUCTIVITY OF SLS TO ENCOURAGE THE GROWTH OF THIS SEGMENT

Selective laser sintering (SLS) uses high-power pulsed laser beams (like CO2 lasers) to fuse particles and form sintered bonds. The dental applications of SLS include manufacturing instrument parts, functional prototypes, and dental implants. SLS can process a wide range of commercialized materials like polymers (simple and composite), plastics (nylon-based materials), ceramics, and green sand. It is more productive than other techniques for manufacturing customized products and does not require supporting structures (unlike SLA and FDM) because it is always covered by a sintered particle. It offers better strength and durability than SLA and does not require post-processing or infiltration of products. Materials that are often used with SLS include ABS, PVC, and PEEK. PEEK frameworks are widely used in Best dental 3D printing solutions as an alternative to metal frameworks that require time-consuming milling or casting procedures. SLS can also be used to fabricate anatomical study models, cutting and drilling guides, and dental models. Its advantages include easy autoclavability of the materials used, complete mechanical functionality of printed objects, and lower cost of the materials if used in larger volumes.

POLYJET PRINTING

HIGH PRECISION AND A WIDE VARIETY OF APPLICATIONS OF POLYJET TECHNOLOGY TO BOOST THE MARKET GROWTH

PolyJet printing preserves thin layers of liquid photopolymer using UV energy. It is capable of printing in 16- micron layers at different levels of hardness (or durometers). PolyJet dental materials are specifically designed for digital dentistry and orthodontic applications, including stone models and aligners. These rigid, opaque materials have a natural-looking peach color and combine extremely accurate detail with high-dimensional stability. This technology is compatible with a wide range of materials (more than 120) and simultaneously combines several materials. The advantages of PolyJet technology, such as precision, smooth surfaces, ultra-fine details, and the ability to manufacture a wide range of products, from plastics to human tissue, are likely to support market growth.

OTHER TECHNOLOGIES

The other technologies used in dental 3D printing are laser beam melting (LBM), direct-metal laser sintering (DMLS), selective laser melting (SLM), LaserCUSING, droplet deposition or extrusion-based technologies, and low-temperature deposition manufacturing (LDM).

DENTAL 3D PRINTING MARKET, BY APPLICATION

PROSTHODONTICS

The availability of various additive manufacturing processes and materials has driven the use of 3D printing to produce different dental prosthetics. Also, the feasibility of 3D printing in prosthodontics has increased over the last few years. Rapid prototyping can be implemented to manufacture surgical implant guides, frameworks for fixed and removable partial dentures, wax patterns for dental prosthesis, zirconia prostheses, and molds for metal castings, maxillofacial prostheses, and complete dentures. One of the major applications of 3D printing in the field of prosthodontics is the manufacturing of dentures. The utilization of dental design software and 3D printing to manufacture dentures offers numerous advantages—low-cost production and accuracy, consistency, high quality, reusability, and reproducibility of 3D-printed dentures. These factors are expected to drive better patient outcomes and boost the market growth for prosthodontics applications in the forecast period.

ORTHODONTICS

In orthodontics, 3D-printed models provided by manufacturers are used by dental labs or clinics to fabricate a comprehensive range of orthodontic products, such as mouth guards, retainers, expanders, and clear aligners. This market is expected to grow in time with the increasing emphasis on aesthetics and appearance.

Orthodontic laboratories are increasingly adopting digital orthodontic dentistry and 3D printers to optimize their businesses and dental offerings and reduce labor-intensive and costly practices. The workflow for 3D printing in orthodontics begins with scanning the patient’s dental anomaly with an intraoral scanner. This is followed by importing scan data into dental CAD software to design orthodontic models or other orthodontic indications. The designed CAD files are then sent to a printer, followed by washing, drying, and post-curing printed parts. Following this, the printed products are used directly or to manufacture clear aligners or retainers over 3D-printed models.

IMPLANTOLOGY

Dental implants, also known as endosseous fixtures, are artificial tooth roots used to substitute missing teeth for supporting restorations. The process of fixing the implant is known as implantology. Implants provide a strong foundation and are ideal for individuals who have lost a tooth/teeth due to periodontal disease or an injury. The aging and edentulous populations show high demand for implants; therefore, their growth over the coming years is expected to form the primary driver for the implantology applications market. According to the WHO, the global geriatric population (aged 65 years and above) will increase from 1,344.2 million (8.5% of the total global population) in 2019 to 2,978.9 million by 2050, indicating significant opportunities for growth.

Over the last few years, the usage of 3D printing in implantology has increased, and this technology has transformed the workflow and standard of dental implants. The location, angulation, and size of implants specific to the site are some of the major factors required to be considered while performing dental implantation. CAD/CAM-guided surgery for dental implant placement is considered a better treatment option than the freehand technique.