3D Printing in Healthcare Market Synopsis

3D Printing in Healthcare Market Size Was Valued at USD 9.62 Billion in 2023, and is Projected to Reach USD 47.45 Billion by 2032, Growing at a CAGR of 19.40% From 2024-2032.

The present application of 3D prints in the medical and associated fields of practice include manufacturing of both purely healthcares and specialized medical service tools such as precise medical equipment, prosthetics, anatomical models for surgery planning and practice. With the use of this technology, it becomes possible to create real-life models of organs and implants that duplicate the need of a specific patient to improve the precision of the operation and in general affect the result in a better way.

• The 3D Printing in Healthcare market is growing at a phenomenal pace primarily due to the versatile nature of the product that has brought revolution in many sector of medical science. Implants and prosthetics and biosurgery, medical use of 3D printing technology for creation of individualized medical devices, body implants, prostheses, and bioprinted tissues and organs are included to this market. This segment has been boosted by this market’s capability to deliver customised healthcare needs through the application of 3D printing. 3D printing makes it possible to develop patient-specific implants and prosthetics through enhancing its manufacturing in comparison to those conventional manufacturing technologies that help bring a “one size fits all” solution. It promotes improved anatomic compatibility to medical devices which makes patients satisfied resulting in better health.
• Moreover, application of 3D printing technology is changing the utilization in the surgery planning and education. Now, through 3D printing it has become possible for surgeons to get the complete anatomic build-up of the patients to be operated so as to conduct operations of higher order – free from any hassles of complications and second best time. In the same respect, 3D printing has been used extensively in the medical field in the manufacturing of models that are used in training the students as well as other professionals in the medical field which makes their learning process even better.
• Another factor being proximity in growth of this market is the improvements taking place in materials and methods of printing. Thus, the application of medical grade polymers and bioinks has increased the possibilities of using 3D printing in health care field. For example, bioinks is used for building living tissues and organ structures which will become the future of regenerative medicine and solutions for organ donor deficit.
• But, like any other market, the 3D printing in healthcare market is not devoid of its hurdles. Government controls, especially regarding the safety of the 3D-printed products such as medical instruments and implants pose a threat to market entry and costs. Also worth pointing out is the fact that 3D printing technology likely comes with a high initial cost which has to do with the equipment and materials necessary for the processes. However, as is demonstrated above, this does not seem to be the case because the advantages that come with 3D printing such as personalisation, precision and innovation are seeing application across the healthcare industry.
• Overall the market of 3D Printing in Healthcare is burgeoning and is expected to expand at a faster pace due to the advancement in the innovation of technology, manufacturing and development of new materials. Advantages such as the possibility to offer tailored therapies, improve the planning of surgeries and contribute to the advancement of regenerative medicine are the trends promoting the growth of the market. This paper has demonstrated that currently, and perhaps more significantly in the future, 3D printing brings significant opportunities to alter healthcare provision and enhance patients’ experiences.

3D Printing in Healthcare Market Trend Analysis

Expansion of Bioprinting Applications

• The rising use of bioprinting in the 3D printing in healthcare market is taken as a shift in the medical technology frontier. It is a technology that is built upon the principles of 3D printing in which cells are placed in a particular order in a structure to form tissues and organs. This technology is the next big thing in regenerative medicine and tissue engineering as it will allow for generation of tissue from patients for transplant, modeling diseases and drug development. The opportunity to print working tissues can help eliminate the problem with a lack of donors, and minimize the chance of transplant rejection with the help of personalized medicine and more efficient therapeutic approaches.
• Further, bioprinting applications are also Wise as it represents the aspects related to healthcare innovations based on the increasing research spending and advancement. There are huge opportunities in the use of 3D printing in healthcare since people require specialized care and there have been improvement in the material used. Moreover, the bioprinting authorities have foreseen the association of the bioprinting technology with other medical technologies, for example, imaging and diagnostics in the near future. This expansion does not only aim at bettering the life of patients but also brings about the strategic plumb of bioprint the future of personalized and regenerative medicine.

Enhanced Surgical Precision and Customization

• The Global Enhanced Surgical Precision and Customization 3D Printing in Healthcare market has continued to grow significantly over the years owing to the need to offer unique and effective medical solutions as well as the available innovations in the 3D printing industries. This market is about the demand for increased accuracy and specificity of implantable devices and prosthetics as well as anatomical models and the need to match them to the individual patient’s need. Incorporating the 3D printing technology in the health sector means that physicians have the ability of designing implant and devices within the body with accuracy hence enhancing surgery and recovery process. It also helps make detailed models of anatomy for pre-operative planning – an understanding that the doctor has about the patient and the disease helps in planning the surgery much more effectively.
• The advancement of productions of 3D printing materials and techniques are continuously made through investments to advance and grow the market of application of 3D printing in healthcare. This has been perceived to improve on the accuracy of surgical procedures and customization with the advancement of the technology. . Organic materials like biocompatible polymers and metals and alloys and the evolving 3D printing techniques which have been widely used in the biomedical field make predictions outgoing and promising for advanced medical devices and solutions. It is expected that with these advancements, it will find applications in various medical specilizations making a contribution to the growth of the market as well as changing the face of surgeries through precision and personalized nature of andrology.

3D Printing in Healthcare Market Segment Analysis:

3D Printing in Healthcare Market Segmented based on Technology , Application, Material , and Medical Speciality.

By Technology, Stereo Lithography segment is expected to dominate the market during the forecast period

• The 3D Printing in Healthcare Market can also be divided based on the types of additives available in the market, which have specific functions regarding the improvement of polyurethane materials. Thus flame retardants are important in enhancing the fire resistance of polyurethane products that aid in enhancing safety of the final products. Antioxidants are added to retard oxidation which leads to deterioration and thus increase the life and strength of polyurethane materials. They show enormous importance as far as the enhancement of chemical reactions during the process of polyurethane synthesis are concerned. They help in enabling one substance to mix with another within the polyurethane to enhance the quality of placing and texture.
• Stabilizers are likewise significant for stability of polyurethane’s physical and chemical properties in the course of its using. They are incorporated to augment the mechanical attributes of PU as well as to increase the product efficiency and decrease the cost. Also, the “Others” category embraces multiple other additives used for varied purposes depending on which sector or the application of polyurethane the additives are meant for. Such a list can be broad due to the diverse nature encountered in the polyurethane industry to explain the various categories required in the production of high-performance polyurethane materials.

By Application , Medical Implants segment held the largest share in 2023

• The 3D printing in healthcare is a revolutionary market within several applications and greatly influences medical implants, prosthetics, wearables, tissue engineering, among others. In the case of medical implants, 3D printing allows the fabrication of patient-specific implants to fit into particular individual anatomic structures for better fit and improved surgical outcomes. Customized implants have become popular in orthopedic and dental applications due to their precision, which reduces surgical time. In the same way, prosthetics 3D printing is also increasingly developing due to demands for personalization, lightness, and affordability. This can create prosthetics fitted to a very specific fit of an individual's body, greatly increasing comfort and functionality, therefore making it a transformative technology within the field of rehabilitation.
• In the context of wearable devices, 3D printing allows for personalized development to include wearables that can attend to very specific medical needs, such as braces, supports, and complex monitoring devices. This gives great room for personalization, which is very critical in ensuring device efficacy and comfort to the patient. Meanwhile, during the same period, new frontiers in tissue engineering were opened by the invention of 3D bioprinting that uses cells and biomaterials for the fabrication of tissue-like structures with capabilities to mimic natural tissues. These are considered assured prospects of organic transplantation and regenerative medicine in the near future. Finally, within the category other, applications are as varied as models used for surgical planning, to pharmaceutical studies where 3D printing is employed in the fabrication of drug delivery systems with geometries impossible to achieve so far. It is for this reason that 3D printing finds its application in the health sector owing to the level of flexibility and ingenuity allowed by the technology.

3D Printing in Healthcare Market Regional Insights:

North America is Expected to Dominate the Market Over the Forecast period

• Current leading geographical segment of the 3D printing in healthcare market is North America and for the forecast period this segment will remain on top of the line because of developed technological platform, increased spending on research and development and surgical healthcare system.. This is backed up by copious key players and innovators which are in the region to offer and establish ground breaking 3D printing technologies. These are artificial limbs, dental and joint replacements, and bioengineered organs that go along with the current increased needs for individualized and accurate medical applications. Apart from this, strong norms in the US and Canada regarding the adoption of safe 3D printing technologies foster the market growth at a faster rate for clinical applications.
• In addition, North America is strengthened by a strong healthcare networks and a high ratio of technological implementation in medical process., on account of comprehensive technological infrastructure, massive investment in research and development, and also due to an unflawed healthcare system. The leading position of the region in 3D printing technology is further supported by a host of key players and innovators who are engaged in the development and implementation of advanced solutions. These are custom prosthetics, implants, and bioprinted tissues that meet the growing demand for personalized and accurate medical solutions. Besides this, strict regulatory frameworks in the U.S. and Canada accelerate the safe introduction of 3D printing technologies into clinical applications, further boosting the market growth.
• Besides, the leading position of North America is enforced by substantial healthcare networks and a high rate of advanced technologies adoption in medical treatment. Furthermore, this area has sufficient funds and grant opportunities for emerging 3D printing in healthcare. On top of this there has also been growth of academic-industry partnerships in the region. With the numeration of chronic diseases as well as the growth in the number of elderly people, the demand for new and cheap medical developments has accelerated. This, in turn, creates call for adoption of 3D printing technologies. North America region will persist to lead as there are significant increased demand by the healthcare organizations and patients in terms of enhancing on the existing treatment options.

Active Key Players in the 3D Printing in Healthcare Market

• Stratasys Ltd. (United States/Israel)
• 3D Systems Corporation (United States)
• GE Additive (United States)
• Materialise NV (Belgium)
• EOS GmbH (Germany)
• SLM Solutions Group AG (Germany)
• Renishaw plc (United Kingdom)
• EnvisionTEC, Inc. (United States)
• Carbon, Inc. (United States)
• Formlabs, Inc. (United States)
• Organovo Holdings, Inc. (United States)
• Prodways Group (France)
• Concept Laser GmbH (Germany)
• ExOne GmbH (Germany)
• CELLINK AB (Sweden) and Others Key Player

Key Industry Developments in the 3D Printing in Healthcare Market

• In April 2024, Fathom Manufacturing acquired GPI Prototype & Manufacturing Services, a prominent metal additive manufacturing services provider. The combined entity, operating under the Fathom brand, is the largest privately held digital manufacturing company in the United States. The acquisition expands Fathom's metal additive manufacturing capabilities, including Direct Metal Laser Sintering (DMLS) and CNC machining, enabling it to serve a broader range of customers across medical, aerospace, defense, and industrial industries.
• In March 2024, EOS GmbH, an industrial 3D printing company, added a new machine to its EOS M 290 segment, the EOS M 290 1Kw. Designed considering serial production, the new Laser Powder Bed Fusion (LPBF) metal additive manufacturing (AM) platform meets the specific requirements of copper and copper alloys, which are often critical to processing for applications such as heat exchangers and inductors.

Chapter 1: Introduction
 1.1 Scope and Coverage

Chapter 2:Executive Summary

Chapter 3: Market Landscape
 3.1 Market Dynamics
  3.1.1 Drivers
  3.1.2 Restraints
  3.1.3 Opportunities
  3.1.4 Challenges
 3.2 Market Trend Analysis
 3.3 PESTLE Analysis
 3.4 Porter's Five Forces Analysis
 3.5 Industry Value Chain Analysis
 3.6 Ecosystem
 3.7 Regulatory Landscape
 3.8 Price Trend Analysis
 3.9 Patent Analysis
 3.10 Technology Evolution
 3.11 Investment Pockets
 3.12 Import-Export Analysis

Chapter 4: 3D Printing in Healthcare Market by Technology
 4.1 3D Printing in Healthcare Market Snapshot and Growth Engine
 4.2 3D Printing in Healthcare Market Overview
 4.3 Stereo Lithography
  4.3.1 Introduction and Market Overview
  4.3.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.3.3 Key Market Trends, Growth Factors and Opportunities
  4.3.4 Stereo Lithography: Geographic Segmentation Analysis
 4.4 Deposition Modeling
  4.4.1 Introduction and Market Overview
  4.4.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.4.3 Key Market Trends, Growth Factors and Opportunities
  4.4.4 Deposition Modeling: Geographic Segmentation Analysis
 4.5 Electron Beam Melting
  4.5.1 Introduction and Market Overview
  4.5.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.5.3 Key Market Trends, Growth Factors and Opportunities
  4.5.4 Electron Beam Melting: Geographic Segmentation Analysis
 4.6 Laser Sintering
  4.6.1 Introduction and Market Overview
  4.6.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.6.3 Key Market Trends, Growth Factors and Opportunities
  4.6.4 Laser Sintering: Geographic Segmentation Analysis
 4.7 Jetting Technology
  4.7.1 Introduction and Market Overview
  4.7.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.7.3 Key Market Trends, Growth Factors and Opportunities
  4.7.4 Jetting Technology: Geographic Segmentation Analysis
 4.8 Laminated Object Manufacturing
  4.8.1 Introduction and Market Overview
  4.8.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.8.3 Key Market Trends, Growth Factors and Opportunities
  4.8.4 Laminated Object Manufacturing: Geographic Segmentation Analysis
 4.9 Other
  4.9.1 Introduction and Market Overview
  4.9.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  4.9.3 Key Market Trends, Growth Factors and Opportunities
  4.9.4 Other: Geographic Segmentation Analysis

Chapter 5: 3D Printing in Healthcare Market by Application
 5.1 3D Printing in Healthcare Market Snapshot and Growth Engine
 5.2 3D Printing in Healthcare Market Overview
 5.3 Medical Implants
  5.3.1 Introduction and Market Overview
  5.3.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  5.3.3 Key Market Trends, Growth Factors and Opportunities
  5.3.4 Medical Implants: Geographic Segmentation Analysis
 5.4 Prosthetics
  5.4.1 Introduction and Market Overview
  5.4.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  5.4.3 Key Market Trends, Growth Factors and Opportunities
  5.4.4 Prosthetics: Geographic Segmentation Analysis
 5.5 Wearable Devices
  5.5.1 Introduction and Market Overview
  5.5.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  5.5.3 Key Market Trends, Growth Factors and Opportunities
  5.5.4 Wearable Devices: Geographic Segmentation Analysis
 5.6 Tissue Engineering
  5.6.1 Introduction and Market Overview
  5.6.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  5.6.3 Key Market Trends, Growth Factors and Opportunities
  5.6.4 Tissue Engineering: Geographic Segmentation Analysis
 5.7 Other
  5.7.1 Introduction and Market Overview
  5.7.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  5.7.3 Key Market Trends, Growth Factors and Opportunities
  5.7.4 Other: Geographic Segmentation Analysis

Chapter 6: 3D Printing in Healthcare Market by Material
 6.1 3D Printing in Healthcare Market Snapshot and Growth Engine
 6.2 3D Printing in Healthcare Market Overview
 6.3 Metal & Alloy
  6.3.1 Introduction and Market Overview
  6.3.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  6.3.3 Key Market Trends, Growth Factors and Opportunities
  6.3.4 Metal & Alloy: Geographic Segmentation Analysis
 6.4 Polymer
  6.4.1 Introduction and Market Overview
  6.4.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  6.4.3 Key Market Trends, Growth Factors and Opportunities
  6.4.4 Polymer: Geographic Segmentation Analysis
 6.5 Other Materials
  6.5.1 Introduction and Market Overview
  6.5.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  6.5.3 Key Market Trends, Growth Factors and Opportunities
  6.5.4 Other Materials: Geographic Segmentation Analysis

Chapter 7: 3D Printing in Healthcare Market by Medical Specialty
 7.1 3D Printing in Healthcare Market Snapshot and Growth Engine
 7.2 3D Printing in Healthcare Market Overview
 7.3 Orthopedics
  7.3.1 Introduction and Market Overview
  7.3.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.3.3 Key Market Trends, Growth Factors and Opportunities
  7.3.4 Orthopedics: Geographic Segmentation Analysis
 7.4 Dental
  7.4.1 Introduction and Market Overview
  7.4.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.4.3 Key Market Trends, Growth Factors and Opportunities
  7.4.4 Dental: Geographic Segmentation Analysis
 7.5 Cardiovascular
  7.5.1 Introduction and Market Overview
  7.5.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.5.3 Key Market Trends, Growth Factors and Opportunities
  7.5.4 Cardiovascular: Geographic Segmentation Analysis
 7.6 Craniomaxillofacial (CMF)
  7.6.1 Introduction and Market Overview
  7.6.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.6.3 Key Market Trends, Growth Factors and Opportunities
  7.6.4 Craniomaxillofacial (CMF): Geographic Segmentation Analysis
 7.7 Neurosurgery
  7.7.1 Introduction and Market Overview
  7.7.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.7.3 Key Market Trends, Growth Factors and Opportunities
  7.7.4 Neurosurgery: Geographic Segmentation Analysis
 7.8 Oncology
  7.8.1 Introduction and Market Overview
  7.8.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.8.3 Key Market Trends, Growth Factors and Opportunities
  7.8.4 Oncology: Geographic Segmentation Analysis
 7.9 Others
  7.9.1 Introduction and Market Overview
  7.9.2 Historic and Forecasted Market Size in Value USD and Volume Units (2017-2032F)
  7.9.3 Key Market Trends, Growth Factors and Opportunities
  7.9.4 Others: Geographic Segmentation Analysis

Chapter 8: Company Profiles and Competitive Analysis
 8.1 Competitive Landscape
  8.1.1 Competitive Benchmarking
  8.1.2 3D Printing in Healthcare Market Share by Manufacturer (2023)
  8.1.3 Industry BCG Matrix
  8.1.4 Heat Map Analysis
  8.1.5 Mergers and Acquisitions
  
 8.2 STRATASYS LTD. (UNITED STATES/ISRAEL)
  8.2.1 Company Overview
  8.2.2 Key Executives
  8.2.3 Company Snapshot
  8.2.4 Role of the Company in the Market
  8.2.5 Sustainability and Social Responsibility
  8.2.6 Operating Business Segments
  8.2.7 Product Portfolio
  8.2.8 Business Performance
  8.2.9 Key Strategic Moves and Recent Developments
  8.2.10 SWOT Analysis
 8.3 3D SYSTEMS CORPORATION (UNITED STATES)
 8.4 GE ADDITIVE (UNITED STATES)
 8.5 MATERIALISE NV (BELGIUM)
 8.6 EOS GMBH (GERMANY)
 8.7 SLM SOLUTIONS GROUP AG (GERMANY)
 8.8 RENISHAW PLC (UNITED KINGDOM)
 8.9 ENVISIONTEC
 8.10 INC. (UNITED STATES)
 8.11 CARBON
 8.12 INC. (UNITED STATES)
 8.13 FORMLABS
 8.14 INC. (UNITED STATES)
 8.15 ORGANOVO HOLDINGS
 8.16 INC. (UNITED STATES)
 8.17 PRODWAYS GROUP (FRANCE)
 8.18 CONCEPT LASER GMBH (GERMANY)
 8.19 EXONE GMBH (GERMANY)
 8.20 CELLINK AB (SWEDEN)
 8.21 OTHERS KEY PLAYER.

Chapter 9: Global 3D Printing in Healthcare Market By Region
 9.1 Overview
 9.2. North America 3D Printing in Healthcare Market
  9.2.1 Key Market Trends, Growth Factors and Opportunities
  9.2.2 Top Key Companies
  9.2.3 Historic and Forecasted Market Size by Segments
  9.2.4 Historic and Forecasted Market Size By Technology
  9.2.4.1 Stereo Lithography
  9.2.4.2 Deposition Modeling
  9.2.4.3 Electron Beam Melting
  9.2.4.4 Laser Sintering
  9.2.4.5 Jetting Technology
  9.2.4.6 Laminated Object Manufacturing
  9.2.4.7 Other
  9.2.5 Historic and Forecasted Market Size By Application
  9.2.5.1 Medical Implants
  9.2.5.2 Prosthetics
  9.2.5.3 Wearable Devices
  9.2.5.4 Tissue Engineering
  9.2.5.5 Other
  9.2.6 Historic and Forecasted Market Size By Material
  9.2.6.1 Metal & Alloy
  9.2.6.2 Polymer
  9.2.6.3 Other Materials
  9.2.7 Historic and Forecasted Market Size By Medical Specialty
  9.2.7.1 Orthopedics
  9.2.7.2 Dental
  9.2.7.3 Cardiovascular
  9.2.7.4 Craniomaxillofacial (CMF)
  9.2.7.5 Neurosurgery
  9.2.7.6 Oncology
  9.2.7.7 Others
  9.2.8 Historic and Forecast Market Size by Country
  9.2.8.1 US
  9.2.8.2 Canada
  9.2.8.3 Mexico
 9.3. Eastern Europe 3D Printing in Healthcare Market
  9.3.1 Key Market Trends, Growth Factors and Opportunities
  9.3.2 Top Key Companies
  9.3.3 Historic and Forecasted Market Size by Segments
  9.3.4 Historic and Forecasted Market Size By Technology
  9.3.4.1 Stereo Lithography
  9.3.4.2 Deposition Modeling
  9.3.4.3 Electron Beam Melting
  9.3.4.4 Laser Sintering
  9.3.4.5 Jetting Technology
  9.3.4.6 Laminated Object Manufacturing
  9.3.4.7 Other
  9.3.5 Historic and Forecasted Market Size By Application
  9.3.5.1 Medical Implants
  9.3.5.2 Prosthetics
  9.3.5.3 Wearable Devices
  9.3.5.4 Tissue Engineering
  9.3.5.5 Other
  9.3.6 Historic and Forecasted Market Size By Material
  9.3.6.1 Metal & Alloy
  9.3.6.2 Polymer
  9.3.6.3 Other Materials
  9.3.7 Historic and Forecasted Market Size By Medical Specialty
  9.3.7.1 Orthopedics
  9.3.7.2 Dental
  9.3.7.3 Cardiovascular
  9.3.7.4 Craniomaxillofacial (CMF)
  9.3.7.5 Neurosurgery
  9.3.7.6 Oncology
  9.3.7.7 Others
  9.3.8 Historic and Forecast Market Size by Country
  9.3.8.1 Bulgaria
  9.3.8.2 The Czech Republic
  9.3.8.3 Hungary
  9.3.8.4 Poland
  9.3.8.5 Romania
  9.3.8.6 Rest of Eastern Europe
 9.4. Western Europe 3D Printing in Healthcare Market
  9.4.1 Key Market Trends, Growth Factors and Opportunities
  9.4.2 Top Key Companies
  9.4.3 Historic and Forecasted Market Size by Segments
  9.4.4 Historic and Forecasted Market Size By Technology
  9.4.4.1 Stereo Lithography
  9.4.4.2 Deposition Modeling
  9.4.4.3 Electron Beam Melting
  9.4.4.4 Laser Sintering
  9.4.4.5 Jetting Technology
  9.4.4.6 Laminated Object Manufacturing
  9.4.4.7 Other
  9.4.5 Historic and Forecasted Market Size By Application
  9.4.5.1 Medical Implants
  9.4.5.2 Prosthetics
  9.4.5.3 Wearable Devices
  9.4.5.4 Tissue Engineering
  9.4.5.5 Other
  9.4.6 Historic and Forecasted Market Size By Material
  9.4.6.1 Metal & Alloy
  9.4.6.2 Polymer
  9.4.6.3 Other Materials
  9.4.7 Historic and Forecasted Market Size By Medical Specialty
  9.4.7.1 Orthopedics
  9.4.7.2 Dental
  9.4.7.3 Cardiovascular
  9.4.7.4 Craniomaxillofacial (CMF)
  9.4.7.5 Neurosurgery
  9.4.7.6 Oncology
  9.4.7.7 Others
  9.4.8 Historic and Forecast Market Size by Country
  9.4.8.1 Germany
  9.4.8.2 UK
  9.4.8.3 France
  9.4.8.4 Netherlands
  9.4.8.5 Italy
  9.4.8.6 Russia
  9.4.8.7 Spain
  9.4.8.8 Rest of Western Europe
 9.5. Asia Pacific 3D Printing in Healthcare Market
  9.5.1 Key Market Trends, Growth Factors and Opportunities
  9.5.2 Top Key Companies
  9.5.3 Historic and Forecasted Market Size by Segments
  9.5.4 Historic and Forecasted Market Size By Technology
  9.5.4.1 Stereo Lithography
  9.5.4.2 Deposition Modeling
  9.5.4.3 Electron Beam Melting
  9.5.4.4 Laser Sintering
  9.5.4.5 Jetting Technology
  9.5.4.6 Laminated Object Manufacturing
  9.5.4.7 Other
  9.5.5 Historic and Forecasted Market Size By Application
  9.5.5.1 Medical Implants
  9.5.5.2 Prosthetics
  9.5.5.3 Wearable Devices
  9.5.5.4 Tissue Engineering
  9.5.5.5 Other
  9.5.6 Historic and Forecasted Market Size By Material
  9.5.6.1 Metal & Alloy
  9.5.6.2 Polymer
  9.5.6.3 Other Materials
  9.5.7 Historic and Forecasted Market Size By Medical Specialty
  9.5.7.1 Orthopedics
  9.5.7.2 Dental
  9.5.7.3 Cardiovascular
  9.5.7.4 Craniomaxillofacial (CMF)
  9.5.7.5 Neurosurgery
  9.5.7.6 Oncology
  9.5.7.7 Others
  9.5.8 Historic and Forecast Market Size by Country
  9.5.8.1 China
  9.5.8.2 India
  9.5.8.3 Japan
  9.5.8.4 South Korea
  9.5.8.5 Malaysia
  9.5.8.6 Thailand
  9.5.8.7 Vietnam
  9.5.8.8 The Philippines
  9.5.8.9 Australia
  9.5.8.10 New Zealand
  9.5.8.11 Rest of APAC
 9.6. Middle East & Africa 3D Printing in Healthcare Market
  9.6.1 Key Market Trends, Growth Factors and Opportunities
  9.6.2 Top Key Companies
  9.6.3 Historic and Forecasted Market Size by Segments
  9.6.4 Historic and Forecasted Market Size By Technology
  9.6.4.1 Stereo Lithography
  9.6.4.2 Deposition Modeling
  9.6.4.3 Electron Beam Melting
  9.6.4.4 Laser Sintering
  9.6.4.5 Jetting Technology
  9.6.4.6 Laminated Object Manufacturing
  9.6.4.7 Other
  9.6.5 Historic and Forecasted Market Size By Application
  9.6.5.1 Medical Implants
  9.6.5.2 Prosthetics
  9.6.5.3 Wearable Devices
  9.6.5.4 Tissue Engineering
  9.6.5.5 Other
  9.6.6 Historic and Forecasted Market Size By Material
  9.6.6.1 Metal & Alloy
  9.6.6.2 Polymer
  9.6.6.3 Other Materials
  9.6.7 Historic and Forecasted Market Size By Medical Specialty
  9.6.7.1 Orthopedics
  9.6.7.2 Dental
  9.6.7.3 Cardiovascular
  9.6.7.4 Craniomaxillofacial (CMF)
  9.6.7.5 Neurosurgery
  9.6.7.6 Oncology
  9.6.7.7 Others
  9.6.8 Historic and Forecast Market Size by Country
  9.6.8.1 Turkey
  9.6.8.2 Bahrain
  9.6.8.3 Kuwait
  9.6.8.4 Saudi Arabia
  9.6.8.5 Qatar
  9.6.8.6 UAE
  9.6.8.7 Israel
  9.6.8.8 South Africa
 9.7. South America 3D Printing in Healthcare Market
  9.7.1 Key Market Trends, Growth Factors and Opportunities
  9.7.2 Top Key Companies
  9.7.3 Historic and Forecasted Market Size by Segments
  9.7.4 Historic and Forecasted Market Size By Technology
  9.7.4.1 Stereo Lithography
  9.7.4.2 Deposition Modeling
  9.7.4.3 Electron Beam Melting
  9.7.4.4 Laser Sintering
  9.7.4.5 Jetting Technology
  9.7.4.6 Laminated Object Manufacturing
  9.7.4.7 Other
  9.7.5 Historic and Forecasted Market Size By Application
  9.7.5.1 Medical Implants
  9.7.5.2 Prosthetics
  9.7.5.3 Wearable Devices
  9.7.5.4 Tissue Engineering
  9.7.5.5 Other
  9.7.6 Historic and Forecasted Market Size By Material
  9.7.6.1 Metal & Alloy
  9.7.6.2 Polymer
  9.7.6.3 Other Materials
  9.7.7 Historic and Forecasted Market Size By Medical Specialty
  9.7.7.1 Orthopedics
  9.7.7.2 Dental
  9.7.7.3 Cardiovascular
  9.7.7.4 Craniomaxillofacial (CMF)
  9.7.7.5 Neurosurgery
  9.7.7.6 Oncology
  9.7.7.7 Others
  9.7.8 Historic and Forecast Market Size by Country
  9.7.8.1 Brazil
  9.7.8.2 Argentina
  9.7.8.3 Rest of SA

Chapter 10 Analyst Viewpoint and Conclusion
10.1 Recommendations and Concluding Analysis
10.2 Potential Market Strategies

Chapter 11 Research Methodology
11.1 Research Process
11.2 Primary Research
11.3 Secondary Research