3D Printing Medical Devices Market : Global Industry Analysis and Forecast (2022-2029)

3D Printing Medical Devices Market size is expected to grow at a CAGR of 16.2% during the forecast period and the market size is expected to reach nearly US$ 8.00 Bn. by 2029. The report includes the analysis of impact of COVID-19 lock-down on the revenue of market leaders, followers, and disrupters. Since lock down was implemented differently in different regions and countries, impact of same is also different by regions and segments. The report has covered the current short term and long term impact on the market, same will help decision makers to prepare the outline for short term and long term strategies for companies by region. Global 3D Printing Medical Devices Market To know about the Research Methodology:-Request Free Sample Report

Global 3D Printing Medical Device Market Dynamics:

The Global 3D Printing Medical Devices Market is driven by increasing demand for applications in the healthcare industry because of public-private funding for 3D printing and technological advancements. This market is expected to grow during the forecast period on account of the numerous technological innovations in this sector. One of the major driving factors for growth in the medical 3D printing industry is the rising demand for patient-specific products in orthopaedics and maxillofacial surgery. Additionally, increased R&D investments, rapidly expanding customer base, increasing the scope of biomedical applications, and wide research and development activities at the academic and industrial level have driven the market growth. Furthermore, associations between academic institutions and companies to accelerate the process of product development has increased market growth. Also, the latest advancements in technologies, growing awareness about the new developments. Now, the prices of 3D models coming down and also the availability of a wide range of material options have increased the adaptability of 3D printing in the healthcare sector. At the same time, the lack of trained caretakers for efficient operation of patient handling equipment, lack of trained professionals, socio-ethical concerns related to the use of 3d-printed products are limiting the market growth. By component, the global 3D printing medical device market is segmented into System/Device, material, software and services. Out of these, the segment of software and services contributed the largest share to the global market in 2021 and is expected to grow at a higher rate during the forecast period. This is the result of already set up printers in the market, and to provide installation services, support and maintenance of these printers, there is a growing demand for software and services segment. The key factor driving the growth of the Software & Services segment is Increasing development in software solutions to manufacturing high-quality 3D-printed medical products.

Global 3D Printing Medical Device Market Regional Insights:

North America dominates the Global 3D Printing Medical Device Market through the forecast period. The largest share is attributed to the increasing demand for organ transplant across the region. Due to an increased investment made by the government to develop advanced 3D printing technologies and applications are some of the factors responsible for the growth of the market in this region. Moreover, a growing number of surgeries due to changing lifestyles is contributing to the growth of the market in this region. The key players of 3D printing medical devices have used several strategies such as new product launches, expansions, agreements, joint ventures, partnerships, acquisitions, and others to increase their footprints in this market. The report includes market shares of global 3D printing medical devices market for various regions. In September 2018, Wacker Chemie AG (Germany) announced the opening of US 3D printing lab for silicone rubber. Through this the company can expand its business for 3D printing technology in the U.S. In November 2017, Koninklijke Philips N.V, announced the agreement with 3D Systems and Stratasys. Through this agreement, the company make stronger their anatomical knowledge that would enhance the impact on clinical trial reviewing complex and multi-disciplinary cases. The objective of the report is to present a comprehensive assessment of the market and contains thoughtful insights, facts, historical data, industry-validated market data and projections with a suitable set of assumptions and methodology. The report also helps in understanding the Global 3D Printing Medical Device Market dynamics, structure by identifying and analysing the market segments and project the global market size. Further, the report also focuses on the competitive analysis of key players by product, price, financial position, product portfolio, growth strategies, and regional presence. The report also provides PEST analysis, PORTER’s analysis, and SWOT analysis to address questions of shareholders to prioritizing the efforts and investment in the near future to the emerging segment in the Global GIS Market.

Global 3D Printing Medical Device Market, Key Highlights:

• Global 3D Printing Medical Device Market analysis and forecast, in terms of value. • Comprehensive study and analysis of market drivers, restraints and opportunities influencing the growth of the Global 3D Printing Medical Device Market • Global 3D Printing Medical Device Market segmentation on the basis of type, source, end-user, and region (country-wise) has been provided. • Global 3D Printing Medical Device Market strategic analysis with respect to individual growth trends, future prospects along with the contribution of various sub-market stakeholders have been considered under the scope of study. • Global 3D Printing Medical Device Market analysis and forecast for five major regions namely North America, Europe, Asia Pacific, the Middle East & Africa (MEA) and Latin America along with country-wise segmentation. • Profiles of key industry players, their strategic perspective, market positioning and analysis of core competencies are further profiled. • Competitive developments, investments, strategic expansion and competitive landscape of the key players operating in the Global 3D Printing Medical Device Market are also profiled.

Global 3D Printing Medical Devices Market Scope: Inquire before buying

Global 3D Printing Medical Devices Market, By Component:

• System/Device • Materials • Software & Services

Global 3D Printing Medical Devices Market, By Technology:

• Droplet Deposition o Fused deposition modeling technology o Low-temperature Deposition Manufacturing o Multiphase Jet Solidification • Photo polymerization o Stereo lithography o Continuous Liquid Interface Production o Two-Photon Polymerization • Laser Beam melting o Selective Laser Sintering o Selective laser melting o Direct Metal Laser Sintering • Electronic Beam Melting • Laminated Object Manufacturing • Three-Dimensional Printing

Global 3D Printing Medical Devices Market, By Application:

• External wearable devices • Clinical study devices • Implants • Tissue engineering

Global 3D Printing Medical Devices Market, By End User:

• Medical and surgical centers • Pharma and biotech companies • Academic institutions

Global 3D Printing Medical Devices Market, By Region:

• North America • Europe • Asia-Pacific • South America • Middle East & Africa

Global 3D Printing Medical Devices Market Key Player

• 3D Systems Corporation • EnvisonTec • Stratasys Ltd. • Arcam AB • Cyfuse Biomedical KK • Organovo Holdings • EOS GmbH • FabRx Ltd. • Materialise N.V. • Concept Laser • SLM Solutions Group AG • Oxford Performance Materials, Inc. • Bio3D Technologies • Laser GmbH • Renishawplc • Prodways Group • 3T RPD Ltd. • Anatmics Pvt. Ltd. • Biomedical Modeling Inc. • Carbon Inc Frequently Asked Questions: 1. Which region has the largest share in Global 3D Printing Medical Devices Market? Ans: North America region holds the highest share in 2021. 2. What is the growth rate of Global 3D Printing Medical Devices Market? Ans: The Global 3D Printing Medical Devices Market is growing at a CAGR of 16.2% % during forecasting period 2022-2029. 3. What is scope of the Global 3D Printing Medical Devices market report? Ans: Global 3D Printing Medical Devices Market report helps with the PESTEL, PORTER, COVID-19 Impact analysis, Recommendations for Investors & Leaders, and market estimation of the forecast period. 4. Who are the key players in Global 3D Printing Medical Devices market? Ans: The important key players in the Global 3D Printing Medical Devices Market are – 3D Systems Corporation, EnvisonTec, Stratasys Ltd., Arcam AB, Cyfuse Biomedical KK, Organovo Holdings, EOS GmbH, FabRx Ltd., Materialise N.V., Concept Laser, SLM Solutions Group AG, Oxford Performance Materials, Inc., Bio3D Technologies, Laser GmbH, Renishawplc, Prodways Group, 3T RPD Ltd., Anatmics Pvt. Ltd., and Biomedical Modeling Inc. 5. What is the study period of this market? Ans: The Global 3D Printing Medical Devices Market is studied from 2021 to 2029.

Global 3D Printing Medical Devices Market

1. Preface 1.1. Report Scope and Market Segmentation 1.2. Research Highlights 1.3. Research Objectives 2. Assumptions and Research Methodology 2.1. Report Assumptions 2.2. Abbreviations 2.3. Research Methodology 2.3.1. Secondary Research 2.3.1.1. Secondary data 2.3.1.2. Secondary Sources 2.3.2. Primary Research 2.3.2.1. Data from Primary Sources 2.3.2.2. Breakdown of Primary Sources 3. Executive Summary : Global3D Printing Medical Devices Market, by Market Value (US$ Bn) 4. Market Overview 4.1. Introduction 4.2. Market Indicator 4.2.1. Drivers 4.2.2. Restraints 4.2.3. Opportunities 4.2.4. Challenges 4.3. Porter’s Analysis 4.4. Value Chain Analysis 4.5. Market Risk Analysis 4.6. SWOT Analysis 4.7 Industry Trends in Global 3D Printing Medical Devices Market 5. Supply Side and Demand Side Indicators 6. Global 3D Printing Medical Devices Market Analysis and Forecast 6.1. Global 3D Printing Medical Devices Market Size & Y-o-Y Growth Analysis 6.1.1. North America 6.1.2. Europe 6.1.3. Asia Pacific 6.1.4. Middle East & Africa 6.1.5. South America 7. Global 3D Printing Medical Devices Market Analysis and Forecast, By Component 7.1. Introduction and Definition 7.2. Key Findings 7.3. Global 3D Printing Medical Devices Market Value Share Analysis, By Component 7.4. Global 3D Printing Medical Devices Market Size (US$ Bn) Forecast, By Component 7.5. Global 3D Printing Medical Devices Market Analysis, By Component 7.6. Global 3D Printing Medical Devices Market Attractiveness Analysis, By Component 8. Global 3D Printing Medical Devices Market Analysis and Forecast, By Technology 8.1. Introduction and Definition 8.2. Key Findings 8.3. Global 3D Printing Medical Devices Market Value Share Analysis, By Technology 8.4. Global 3D Printing Medical Devices Market Size (US$ Bn) Forecast, By Technology 8.5. Global 3D Printing Medical Devices Market Analysis, By Technology 8.6. Global 3D Printing Medical Devices Market Attractiveness Analysis, By Technology 9. Global 3D Printing Medical Devices Market Analysis and Forecast, By Application 9.1. Introduction and Definition 9.2. Key Findings 9.3. Global 3D Printing Medical Devices Market Value Share Analysis, By Application 9.4. Global 3D Printing Medical Devices Market Size (US$ Bn) Forecast, By Application 9.5. Global 3D Printing Medical Devices Market Analysis, By Application 9.6. Global 3D Printing Medical Devices Market Attractiveness Analysis, By Application 10. Global 3D Printing Medical Devices Market Analysis and Forecast, By End User 10.1. Introduction and Definition 10.2. Key Findings 10.3. Global 3D Printing Medical Devices Market Value Share Analysis, By End User 10.4. Global 3D Printing Medical Devices Market Size (US$ Bn) Forecast, By End User 10.5. Global 3D Printing Medical Devices Market Analysis, By End User 10.6. Global 3D Printing Medical Devices Market Attractiveness Analysis, By End User 11. Global 3D Printing Medical Devices Market Analysis, by Region 11.1. Global 3D Printing Medical Devices Market Value Share Analysis, by Region 11.2. Global 3D Printing Medical Devices Market Size (US$ Bn) Forecast, by Region 11.3. Global 3D Printing Medical Devices Market Attractiveness Analysis, by Region 12. North America 3D Printing Medical Devices Market Analysis 12.1. Key Findings 12.2. North America 3D Printing Medical Devices Market Overview 12.3. North America 3D Printing Medical Devices Market Value Share Analysis, By Component 12.4. North America 3D Printing Medical Devices Market Forecast, By Component 12.4.1. System/Device 12.4.2. Materials 12.4.3. Software & Services 12.5. North America 3D Printing Medical Devices Market Value Share Analysis, By Technology 12.6. North America 3D Printing Medical Devices Market Forecast, By Technology 12.6.1. Droplet Deposition 12.6.1.1. Fused deposition modeling technology 12.6.1.2. Low-temperature Deposition Manufacturing 12.6.1.3. Multiphase Jet Solidification 12.6.2. Photo polymerization 12.6.2.1. Stereo lithography 12.6.2.2. Continuous Liquid Interface Production 12.6.2.3. Two-Photon Polymerization 12.6.3. Laser Beam melting 12.6.3.1. Selective Laser Sintering 12.6.3.2. Selective laser melting 12.6.3.3. Direct Metal Laser Sintering 12.6.4. Electronic Beam Melting 12.6.5. Laminated Object Manufacturing 12.6.6. Three-Dimensional Printing 12.7. North America 3D Printing Medical Devices Market Value Share Analysis, By Application 12.8. North America 3D Printing Medical Devices Market Forecast, By Application 12.8.1. External wearable devices 12.8.2. Clinical study devices 12.8.3. Implants 12.8.4. Tissue engineering 12.9. North America 3D Printing Medical Devices Market Value Share Analysis, By End User 12.10. North America 3D Printing Medical Devices Market Forecast, By End User 12.10.1. Medical and surgical centers 12.10.2. Pharma and biotech companies 12.10.3. Academic institutions 12.11. North America 3D Printing Medical Devices Market Value Share Analysis, by Country 12.12. North America 3D Printing Medical Devices Market Forecast, by Country 12.12.1. U.S. 12.12.2. Canada 12.13. North America 3D Printing Medical Devices Market Analysis, by Country 12.14. U.S. 3D Printing Medical Devices Market Forecast, By Component 12.14.1. System/Device 12.14.2. Materials 12.14.3. Software & Services 12.15. U.S. 3D Printing Medical Devices Market Forecast, By Technology 12.15.1. Droplet Deposition 12.15.1.1. Fused deposition modeling technology 12.15.1.2. Low-temperature Deposition Manufacturing 12.15.1.3. Multiphase Jet Solidification 12.15.2. Photo polymerization 12.15.2.1. Stereo lithography 12.15.2.2. Continuous Liquid Interface Production 12.15.2.3. Two-Photon Polymerization 12.15.3. Laser Beam melting 12.15.3.1. Selective Laser Sintering 12.15.3.2. Selective laser melting 12.15.3.3. Direct Metal Laser Sintering 12.15.4. Electronic Beam Melting 12.15.5. Laminated Object Manufacturing 12.15.6. Three-Dimensional Printing 12.16. U.S. 3D Printing Medical Devices Market Forecast, By Application 12.16.1. External wearable devices 12.16.2. Clinical study devices 12.16.3. Implants 12.16.4. Tissue engineering 12.17. U.S. 3D Printing Medical Devices Market Forecast, By End User 12.17.1. Medical and surgical centers 12.17.2. Pharma and biotech companies 12.17.3. Academic institutions 12.18. Canada 3D Printing Medical Devices Market Forecast, By Component 12.18.1. System/Device 12.18.2. Materials 12.18.3. Software & Services 12.19. Canada 3D Printing Medical Devices Market Forecast, By Technology 12.19.1. Droplet Deposition 12.19.1.1. Fused deposition modeling technology 12.19.1.2. Low-temperature Deposition Manufacturing 12.19.1.3. Multiphase Jet Solidification 12.19.2. Photo polymerization 12.19.2.1. Stereo lithography 12.19.2.2. Continuous Liquid Interface Production 12.19.2.3. Two-Photon Polymerization 12.19.3. Laser Beam melting 12.19.3.1. Selective Laser Sintering 12.19.3.2. Selective laser melting 12.19.3.3. Direct Metal Laser Sintering 12.19.4. Electronic Beam Melting 12.19.5. Laminated Object Manufacturing 12.19.6. Three-Dimensional Printing 12.20. Canada 3D Printing Medical Devices Market Forecast, By Application 12.20.1. External wearable devices 12.20.2. Clinical study devices 12.20.3. Implants 12.20.4. Tissue engineering 12.21. Canada 3D Printing Medical Devices Market Forecast, By End User 12.21.1. Medical and surgical centers 12.21.2. Pharma and biotech companies 12.21.3. Academic institutions 12.22. North America 3D Printing Medical Devices Market Attractiveness Analysis 12.22.1. By Component 12.22.2. By Technology 12.22.3. By Application 12.22.4. By End User 12.23. PEST Analysis 12.24. Key Trends 12.25. Key Development 13. Europe 3D Printing Medical Devices Market Analysis 13.1. Key Findings 13.2. Europe 3D Printing Medical Devices Market Overview 13.3. Europe 3D Printing Medical Devices Market Value Share Analysis, By Component 13.4. Europe 3D Printing Medical Devices Market Forecast, By Component 13.4.1. System/Device 13.4.2. Materials 13.4.3. Software & Services 13.5. Europe 3D Printing Medical Devices Market Value Share Analysis, By Technology 13.6. Europe 3D Printing Medical Devices Market Forecast, By Technology 13.6.1. Droplet Deposition 13.6.1.1. Fused deposition modeling technology 13.6.1.2. Low-temperature Deposition Manufacturing 13.6.1.3. Multiphase Jet Solidification 13.6.2. Photo polymerization 13.6.2.1. Stereo lithography 13.6.2.2. Continuous Liquid Interface Production 13.6.2.3. Two-Photon Polymerization 13.6.3. Laser Beam melting 13.6.3.1. Selective Laser Sintering 13.6.3.2. Selective laser melting 13.6.3.3. Direct Metal Laser Sintering 13.6.4. Electronic Beam Melting 13.6.5. Laminated Object Manufacturing 13.6.6. Three-Dimensional Printing 13.7. Europe 3D Printing Medical Devices Market Value Share Analysis, By Application 13.8. Europe 3D Printing Medical Devices Market Forecast, By Application 13.8.1. External wearable devices 13.8.2. Clinical study devices 13.8.3. Implants 13.8.4. Tissue engineering 13.9. Europe 3D Printing Medical Devices Market Value Share Analysis, By End User 13.10. Europe 3D Printing Medical Devices Market Forecast, By End User 13.10.1. Medical and surgical centers 13.10.2. Pharma and biotech companies 13.10.3. Academic institutions 13.11. Others Europe 3D Printing Medical Devices Market Value Share Analysis, by Country 13.12. Europe 3D Printing Medical Devices Market Forecast, by Country 13.12.1. Germany 13.12.2. U.K. 13.12.3. France 13.12.4. Italy 13.12.5. Spain 13.12.6. Rest of Europe 13.13. Europe 3D Printing Medical Devices Market Analysis, by Country 13.14. Germany 3D Printing Medical Devices Market Forecast, By Component 13.14.1. System/Device 13.14.2. Materials 13.14.3. Software & Services 13.15. Germany 3D Printing Medical Devices Market Forecast, By Technology 13.15.1. Droplet Deposition 13.15.1.1. Fused deposition modeling technology 13.15.1.2. Low-temperature Deposition Manufacturing 13.15.1.3. Multiphase Jet Solidification 13.15.2. Photo polymerization 13.15.2.1. Stereo lithography 13.15.2.2. Continuous Liquid Interface Production 13.15.2.3. Two-Photon Polymerization 13.15.3. Laser Beam melting 13.15.3.1. Selective Laser Sintering 13.15.3.2. Selective laser melting 13.15.3.3. Direct Metal Laser Sintering 13.15.4. Electronic Beam Melting 13.15.5. Laminated Object Manufacturing 13.15.6. Three-Dimensional Printing 13.16. Germany 3D Printing Medical Devices Market Forecast, By Application 13.16.1. External wearable devices 13.16.2. Clinical study devices 13.16.3. Implants 13.16.4. Tissue engineering 13.17. Germany 3D Printing Medical Devices Market Forecast, By End User 13.17.1. Medical and surgical centers 13.17.2. Pharma and biotech companies 13.17.3. Academic institutions 13.18. U.K. 3D Printing Medical Devices Market Forecast, By Component 13.18.1. System/Device 13.18.2. Materials 13.18.3. Software & Services 13.19. U.K. 3D Printing Medical Devices Market Forecast, By Technology 13.19.1. Droplet Deposition 13.19.1.1. Fused deposition modeling technology 13.19.1.2. Low-temperature Deposition Manufacturing 13.19.1.3. Multiphase Jet Solidification 13.19.2. Photo polymerization 13.19.2.1. Stereo lithography 13.19.2.2. Continuous Liquid Interface Production 13.19.2.3. Two-Photon Polymerization 13.19.3. Laser Beam melting 13.19.3.1. Selective Laser Sintering 13.19.3.2. Selective laser melting 13.19.3.3. Direct Metal Laser Sintering 13.19.4. Electronic Beam Melting 13.19.5. Laminated Object Manufacturing 13.19.6. Three-Dimensional Printing 13.20. U.K. 3D Printing Medical Devices Market Forecast, By Application 13.20.1. External wearable devices 13.20.2. Clinical study devices 13.20.3. Implants 13.20.4. Tissue engineering 13.21. U.K. 3D Printing Medical Devices Market Forecast, By End User 13.21.1. Medical and surgical centers 13.21.2. Pharma and biotech companies 13.21.3. Academic institutions 13.22. France 3D Printing Medical Devices Market Forecast, By Component 13.22.1. System/Device 13.22.2. Materials 13.22.3. Software & Services 13.23. France 3D Printing Medical Devices Market Forecast, By Technology 13.23.1. Droplet Deposition 13.23.1.1. Fused deposition modeling technology 13.23.1.2. Low-temperature Deposition Manufacturing 13.23.1.3. Multiphase Jet Solidification 13.23.2. Photo polymerization 13.23.2.1. Stereo lithography 13.23.2.2. Continuous Liquid Interface Production 13.23.2.3. Two-Photon Polymerization 13.23.3. Laser Beam melting 13.23.3.1. Selective Laser Sintering 13.23.3.2. Selective laser melting 13.23.3.3. Direct Metal Laser Sintering 13.23.4. Electronic Beam Melting 13.23.5. Laminated Object Manufacturing 13.23.6. Three-Dimensional Printing 13.24. France 3D Printing Medical Devices Market Forecast, By Application 13.24.1. External wearable devices 13.24.2. Clinical study devices 13.24.3. Implants 13.24.4. Tissue engineering 13.25. France 3D Printing Medical Devices Market Forecast, By End User 13.25.1. Medical and surgical centers 13.25.2. Pharma and biotech companies 13.25.3. Academic institutions 13.26. Italy 3D Printing Medical Devices Market Forecast, By Component 13.26.1. System/Device 13.26.2. Materials 13.26.3. Software & Services 13.27. Italy 3D Printing Medical Devices Market Forecast, By Technology 13.27.1. Droplet Deposition 13.27.1.1. Fused deposition modeling technology 13.27.1.2. Low-temperature Deposition Manufacturing 13.27.1.3. Multiphase Jet Solidification 13.27.2. Photo polymerization 13.27.2.1. Stereo lithography 13.27.2.2. Continuous Liquid Interface Production 13.27.2.3. Two-Photon Polymerization 13.27.3. Laser Beam melting 13.27.3.1. Selective Laser Sintering 13.27.3.2. Selective laser melting 13.27.3.3. Direct Metal Laser Sintering 13.27.4. Electronic Beam Melting 13.27.5. Laminated Object Manufacturing 13.27.6. Three-Dimensional Printing 13.28. Italy 3D Printing Medical Devices Market Forecast, By Application 13.28.1. External wearable devices 13.28.2. Clinical study devices 13.28.3. Implants 13.28.4. Tissue engineering 13.29. Italy 3D Printing Medical Devices Market Forecast, By End User 13.29.1. Medical and surgical centers 13.29.2. Pharma and biotech companies 13.29.3. Academic institutions 13.30. Spain 3D Printing Medical Devices Market Forecast, By Component 13.30.1. System/Device 13.30.2. Materials 13.30.3. Software & Services 13.31. Spain 3D Printing Medical Devices Market Forecast, By Technology 13.31.1. Droplet Deposition 13.31.1.1. Fused deposition modeling technology 13.31.1.2. Low-temperature Deposition Manufacturing 13.31.1.3. Multiphase Jet Solidification 13.31.2. Photo polymerization 13.31.2.1. Stereo lithography 13.31.2.2. Continuous Liquid Interface Production 13.31.2.3. Two-Photon Polymerization 13.31.3. Laser Beam melting 13.31.3.1. Selective Laser Sintering 13.31.3.2. Selective laser melting 13.31.3.3. Direct Metal Laser Sintering 13.31.4. Electronic Beam Melting 13.31.5. Laminated Object Manufacturing 13.31.6. Three-Dimensional Printing 13.32. Spain 3D Printing Medical Devices Market Forecast, By Application 13.32.1. External wearable devices 13.32.2. Clinical study devices 13.32.3. Implants 13.32.4. Tissue engineering 13.33. Spain 3D Printing Medical Devices Market Forecast, By End User 13.33.1. Medical and surgical centers 13.33.2. Pharma and biotech companies 13.33.3. Academic institutions 13.34. Rest of Europe 3D Printing Medical Devices Market Forecast, By Component 13.34.1. System/Device 13.34.2. Materials 13.34.3. Software & Services 13.35. Rest of Europe 3D Printing Medical Devices Market Forecast, By Technology 13.35.1. Droplet Deposition 13.35.1.1. Fused deposition modeling technology 13.35.1.2. Low-temperature Deposition Manufacturing 13.35.1.3. Multiphase Jet Solidification 13.35.2. Photo polymerization 13.35.2.1. Stereo lithography 13.35.2.2. Continuous Liquid Interface Production 13.35.2.3. Two-Photon Polymerization 13.35.3. Laser Beam melting 13.35.3.1. Selective Laser Sintering 13.35.3.2. Selective laser melting 13.35.3.3. Direct Metal Laser Sintering 13.35.4. Electronic Beam Melting 13.35.5. Laminated Object Manufacturing 13.35.6. Three-Dimensional Printing 13.36. Rest of Europe 3D Printing Medical Devices Market Forecast, By Application 13.36.1. External wearable devices 13.36.2. Clinical study devices 13.36.3. Implants 13.36.4. Tissue engineering 13.37. Rest Of Europe 3D Printing Medical Devices Market Forecast, By End User 13.37.1. Medical and surgical centers 13.37.2. Pharma and biotech companies 13.37.3. Academic institutions 13.38. Europe 3D Printing Medical Devices Market Attractiveness Analysis 13.38.1. By Component 13.38.2. By Technology 13.38.3. By Application 13.38.4. By End User 13.39. PEST Analysis 13.40. Key Trends 13.41. Key Development 14. Asia Pacific 3D Printing Medical Devices Market Analysis 14.1. Key Findings 14.2. Asia Pacific 3D Printing Medical Devices Market Overview 14.3. Asia Pacific 3D Printing Medical Devices Market Value Share Analysis, By Component 14.4. Asia Pacific 3D Printing Medical Devices Market Forecast, By Component 14.4.1. System/Device 14.4.2. Materials 14.4.3. Software & Services 14.5. Asia Pacific 3D Printing Medical Devices Market Value Share Analysis, By Technology 14.6. Asia Pacific 3D Printing Medical Devices Market Forecast, By Technology 14.6.1. Droplet Deposition 14.6.1.1. Fused deposition modeling technology 14.6.1.2. Low-temperature Deposition Manufacturing 14.6.1.3. Multiphase Jet Solidification 14.6.2. Photo polymerization 14.6.2.1. Stereo lithography 14.6.2.2. Continuous Liquid Interface Production 14.6.2.3. Two-Photon Polymerization 14.6.3. Laser Beam melting 14.6.3.1. Selective Laser Sintering 14.6.3.2. Selective laser melting 14.6.3.3. Direct Metal Laser Sintering 14.6.4. Electronic Beam Melting 14.6.5. Laminated Object Manufacturing 14.6.6. Three-Dimensional Printing 14.7. Asia Pacific 3D Printing Medical Devices Market Value Share Analysis, By Application 14.8. Asia Pacific 3D Printing Medical Devices Market Forecast, By Application 14.8.1. External wearable devices 14.8.2. Clinical study devices 14.8.3. Implants 14.8.4. Tissue engineering 14.9. Asia Pacific 3D Printing Medical Devices Market Value Share Analysis, By End User 14.10. Asia Pacific 3D Printing Medical Devices Market Forecast, By End User 14.10.1. Medical and surgical centers 14.10.2. Pharma and biotech companies 14.10.3. Academic institutions 14.11. Asia Pacific 3D Printing Medical Devices Market Value Share Analysis, by Country 14.12. Asia Pacific 3D Printing Medical Devices Market Forecast, by Country 14.12.1. China 14.12.2. India 14.12.3. Japan 14.12.4. ASEAN 14.12.5. Rest of Asia Pacific 14.13. Asia Pacific 3D Printing Medical Devices Market Analysis, by Country 14.14. China 3D Printing Medical Devices Market Forecast, By Component 14.14.1. System/Device 14.14.2. Materials 14.14.3. Software & Services 14.15. China 3D Printing Medical Devices Market Forecast, By Technology 14.15.1. Droplet Deposition 14.15.1.1. Fused deposition modeling technology 14.15.1.2. Low-temperature Deposition Manufacturing 14.15.1.3. Multiphase Jet Solidification 14.15.2. Photo polymerization 14.15.2.1. Stereo lithography 14.15.2.2. Continuous Liquid Interface Production 14.15.2.3. Two-Photon Polymerization 14.15.3. Laser Beam melting 14.15.3.1. Selective Laser Sintering 14.15.3.2. Selective laser melting 14.15.3.3. Direct Metal Laser Sintering 14.15.4. Electronic Beam Melting 14.15.5. Laminated Object Manufacturing 14.15.6. Three-Dimensional Printing 14.16. China 3D Printing Medical Devices Market Forecast, By Application 14.16.1. External wearable devices 14.16.2. Clinical study devices 14.16.3. Implants 14.16.4. Tissue engineering 14.17. China 3D Printing Medical Devices Market Forecast, By End User 14.17.1. Medical and surgical centers 14.17.2. Pharma and biotech companies 14.17.3. Academic institutions 14.18. India 3D Printing Medical Devices Market Forecast, By Component 14.18.1. System/Device 14.18.2. Materials 14.18.3. Software & Services 14.19. India 3D Printing Medical Devices Market Forecast, By Technology 14.19.1. Droplet Deposition 14.19.1.1. Fused deposition modeling technology 14.19.1.2. Low-temperature Deposition Manufacturing 14.19.1.3. Multiphase Jet Solidification 14.19.2. Photo polymerization 14.19.2.1. Stereo lithography 14.19.2.2. Continuous Liquid Interface Production 14.19.2.3. Two-Photon Polymerization 14.19.3. Laser Beam melting 14.19.3.1. Selective Laser Sintering 14.19.3.2. Selective laser melting 14.19.3.3. Direct Metal Laser Sintering 14.19.4. Electronic Beam Melting 14.19.5. Laminated Object Manufacturing 14.19.6. Three-Dimensional Printing 14.20. India 3D Printing Medical Devices Market Forecast, By Application 14.20.1. External wearable devices 14.20.2. Clinical study devices 14.20.3. Implants 14.20.4. Tissue engineering 14.21. India 3D Printing Medical Devices Market Forecast, By End User 14.21.1. Medical and surgical centers 14.21.2. Pharma and biotech companies 14.21.3. Academic institutions 14.22. Japan 3D Printing Medical Devices Market Forecast, By Component 14.22.1. System/Device 14.22.2. Materials 14.22.3. Software & Services 14.23. Japan 3D Printing Medical Devices Market Forecast, By Technology 14.23.1. Droplet Deposition 14.23.1.1. Fused deposition modeling technology 14.23.1.2. Low-temperature Deposition Manufacturing 14.23.1.3. Multiphase Jet Solidification 14.23.2. Photo polymerization 14.23.2.1. Stereo lithography 14.23.2.2. Continuous Liquid Interface Production 14.23.2.3. Two-Photon Polymerization 14.23.3. Laser Beam melting 14.23.3.1. Selective Laser Sintering 14.23.3.2. Selective laser melting 14.23.3.3. Direct Metal Laser Sintering 14.23.4. Electronic Beam Melting 14.23.5. Laminated Object Manufacturing 14.23.6. Three-Dimensional Printing 14.24. Japan 3D Printing Medical Devices Market Forecast, By Application 14.24.1. External wearable devices 14.24.2. Clinical study devices 14.24.3. Implants 14.24.4. Tissue engineering 14.25. Japan 3D Printing Medical Devices Market Forecast, By End User 14.25.1. Medical and surgical centers 14.25.2. Pharma and biotech companies 14.25.3. Academic institutions 14.26. ASEAN 3D Printing Medical Devices Market Forecast, By Component 14.26.1. System/Device 14.26.2. Materials 14.26.3. Software & Services 14.27. ASEAN 3D Printing Medical Devices Market Forecast, By Technology 14.27.1. Droplet Deposition 14.27.1.1. Fused deposition modeling technology 14.27.1.2. Low-temperature Deposition Manufacturing 14.27.1.3. Multiphase Jet Solidification 14.27.2. Photo polymerization 14.27.2.1. Stereo lithography 14.27.2.2. Continuous Liquid Interface Production 14.27.2.3. Two-Photon Polymerization 14.27.3. Laser Beam melting 14.27.3.1. Selective Laser Sintering 14.27.3.2. Selective laser melting 14.27.3.3. Direct Metal Laser Sintering 14.27.4. Electronic Beam Melting 14.27.5. Laminated Object Manufacturing 14.27.6. Three-Dimensional Printing 14.28. ASEAN 3D Printing Medical Devices Market Forecast, By Application 14.28.1. External wearable devices 14.28.2. Clinical study devices 14.28.3. Implants 14.28.4. Tissue engineering 14.29. ASEAN 3D Printing Medical Devices Market Forecast, By End User 14.29.1. Medical and surgical centers 14.29.2. Pharma and biotech companies 14.29.3. Academic institutions 14.30. Rest of Asia Pacific 3D Printing Medical Devices Market Forecast, By Component 14.30.1. System/Device 14.30.2. Materials 14.30.3. Software & Services 14.31. Rest of Asia Pacific 3D Printing Medical Devices Market Forecast, By Technology 14.31.1. Droplet Deposition 14.31.1.1. Fused deposition modeling technology 14.31.1.2. Low-temperature Deposition Manufacturing 14.31.1.3. Multiphase Jet Solidification 14.31.2. Photo polymerization 14.31.2.1. Stereo lithography 14.31.2.2. Continuous Liquid Interface Production 14.31.2.3. Two-Photon Polymerization 14.31.3. Laser Beam melting 14.31.3.1. Selective Laser Sintering 14.31.3.2. Selective laser melting 14.31.3.3. Direct Metal Laser Sintering 14.31.4. Electronic Beam Melting 14.31.5. Laminated Object Manufacturing 14.31.6. Three-Dimensional Printing 14.32. Rest of Asia Pacific 3D Printing Medical Devices Market Forecast, By Application 14.32.1. External wearable devices 14.32.2. Clinical study devices 14.32.3. Implants 14.32.4. Tissue engineering 14.33. Rest of Asia Pacific 3D Printing Medical Devices Market Forecast, By End User 14.33.1. Medical and surgical centers 14.33.2. Pharma and biotech companies 14.33.3. Academic institutions 14.34. Asia Pacific 3D Printing Medical Devices Market Attractiveness Analysis 14.34.1. By Component 14.34.2. By Technology 14.34.3. By Application 14.34.4. By End User 14.35. PEST Analysis 14.36. Key Trends 14.37. Key Development 15. Middle East & Africa 3D Printing Medical Devices Market Analysis 15.1. Key Findings 15.2. Middle East & Africa 3D Printing Medical Devices Market Overview 15.3. Middle East & Africa 3D Printing Medical Devices Market Value Share Analysis, By Component 15.4. Middle East & Africa 3D Printing Medical Devices Market Forecast, By Component 15.4.1. System/Device 15.4.2. Materials 15.4.3. Software & Services 15.5. Middle East & Africa 3D Printing Medical Devices Market Value Share Analysis, By Technology 15.6. Middle East & Africa 3D Printing Medical Devices Market Forecast, By Technology 15.6.1. Droplet Deposition 15.6.1.1. Fused deposition modeling technology 15.6.1.2. Low-temperature Deposition Manufacturing 15.6.1.3. Multiphase Jet Solidification 15.6.2. Photo polymerization 15.6.2.1. Stereo lithography 15.6.2.2. Continuous Liquid Interface Production 15.6.2.3. Two-Photon Polymerization 15.6.3. Laser Beam melting 15.6.3.1. Selective Laser Sintering 15.6.3.2. Selective laser melting 15.6.3.3. Direct Metal Laser Sintering 15.6.4. Electronic Beam Melting 15.6.5. Laminated Object Manufacturing 15.6.6. Three-Dimensional Printing 15.7. Middle East & Africa 3D Printing Medical Devices Market Value Share Analysis, By Application 15.8. Middle East & Africa 3D Printing Medical Devices Market Forecast, By Application 15.8.1. External wearable devices 15.8.2. Clinical study devices 15.8.3. Implants 15.8.4. Tissue engineering 15.9. Middle East & Africa 3D Printing Medical Devices Market Value Share Analysis, By End User 15.10. Middle East & Africa 3D Printing Medical Devices Market Forecast, By End User 15.10.1. Medical and surgical centers 15.10.2. Pharma and biotech companies 15.10.3. Academic institutions 15.11. Middle East & Africa 3D Printing Medical Devices Market Value Share Analysis, by Country 15.12. Middle East & Africa 3D Printing Medical Devices Market Forecast, by Country 15.12.1. GCC 15.12.2. South Africa 15.12.3. Rest of Middle East & Africa 15.13. Middle East & Africa 3D Printing Medical Devices Market Analysis, by Country 15.14. GCC 3D Printing Medical Devices Market Forecast, By Component 15.14.1. System/Device 15.14.2. Materials 15.14.3. Software & Services 15.15. GCC 3D Printing Medical Devices Market Forecast, By Technology 15.15.1. Droplet Deposition 15.15.1.1. Fused deposition modeling technology 15.15.1.2. Low-temperature Deposition Manufacturing 15.15.1.3. Multiphase Jet Solidification 15.15.2. Photo polymerization 15.15.2.1. Stereo lithography 15.15.2.2. Continuous Liquid Interface Production 15.15.2.3. Two-Photon Polymerization 15.15.3. Laser Beam melting 15.15.3.1. Selective Laser Sintering 15.15.3.2. Selective laser melting 15.15.3.3. Direct Metal Laser Sintering 15.15.4. Electronic Beam Melting 15.15.5. Laminated Object Manufacturing 15.15.6. Three-Dimensional Printing 15.16. GCC 3D Printing Medical Devices Market Forecast, By Application 15.16.1. External wearable devices 15.16.2. Clinical study devices 15.16.3. Implants 15.16.4. Tissue engineering 15.17. GCC 3D Printing Medical Devices Market Forecast, By End User 15.17.1. Medical and surgical centers 15.17.2. Pharma and biotech companies 15.17.3. Academic institutions 15.18. South Africa 3D Printing Medical Devices Market Forecast, By Component 15.18.1. System/Device 15.18.2. Materials 15.18.3. Software & Services 15.19. South Africa 3D Printing Medical Devices Market Forecast, By Technology 15.19.1. Droplet Deposition 15.19.1.1. Fused deposition modeling technology 15.19.1.2. Low-temperature Deposition Manufacturing 15.19.1.3. Multiphase Jet Solidification 15.19.2. Photo polymerization 15.19.2.1. Stereo lithography 15.19.2.2. Continuous Liquid Interface Production 15.19.2.3. Two-Photon Polymerization 15.19.3. Laser Beam melting 15.19.3.1. Selective Laser Sintering 15.19.3.2. Selective laser melting 15.19.3.3. Direct Metal Laser Sintering 15.19.4. Electronic Beam Melting 15.19.5. Laminated Object Manufacturing 15.19.6. Three-Dimensional Printing 15.20. South Africa 3D Printing Medical Devices Market Forecast, By Application 15.20.1. External wearable devices 15.20.2. Clinical study devices 15.20.3. Implants 15.20.4. Tissue engineering 15.21. South Africa 3D Printing Medical Devices Market Forecast, By End User 15.21.1. Medical and surgical centers 15.21.2. Pharma and biotech companies 15.21.3. Academic institutions 15.22. Rest of Middle East & Africa 3D Printing Medical Devices Market Forecast, By Component 15.22.1. System/Device 15.22.2. Materials 15.22.3. Software & Services 15.23. Rest of Middle East & Africa 3D Printing Medical Devices Market Forecast, By Technology 15.23.1. Droplet Deposition 15.23.1.1. Fused deposition modeling technology 15.23.1.2. Low-temperature Deposition Manufacturing 15.23.1.3. Multiphase Jet Solidification 15.23.2. Photo polymerization 15.23.2.1. Stereo lithography 15.23.2.2. Continuous Liquid Interface Production 15.23.2.3. Two-Photon Polymerization 15.23.3. Laser Beam melting 15.23.3.1. Selective Laser Sintering 15.23.3.2. Selective laser melting 15.23.3.3. Direct Metal Laser Sintering 15.23.4. Electronic Beam Melting 15.23.5. Laminated Object Manufacturing 15.23.6. Three-Dimensional Printing 15.24. Rest of Middle East & Africa 3D Printing Medical Devices Market Forecast, By Application 15.24.1. External wearable devices 15.24.2. Clinical study devices 15.24.3. Implants 15.24.4. Tissue engineering 15.25. Rest of Middle East & Africa 3D Printing Medical Devices Market Forecast, By End User 15.25.1. Medical and surgical centers 15.25.2. Pharma and biotech companies 15.25.3. Academic institutions 15.26. Middle East & Africa 3D Printing Medical Devices Market Attractiveness Analysis 15.26.1. By Component 15.26.2. By Technology 15.26.3. By Application 15.26.4. By End User 15.27. PEST Analysis 15.28. Key Trends 15.29. Key Development 16. South America 3D Printing Medical Devices Market Analysis 16.1. Key Findings 16.2. South America 3D Printing Medical Devices Market Overview 16.3. South America 3D Printing Medical Devices Market Value Share Analysis, By Component 16.4. South America 3D Printing Medical Devices Market Forecast, By Component 16.4.1. System/Device 16.4.2. Materials 16.4.3. Software & Services 16.5. South America 3D Printing Medical Devices Market Value Share Analysis, By Technology 16.6. South America 3D Printing Medical Devices Market Forecast, By Technology 16.6.1. Droplet Deposition 16.6.1.1. Fused deposition modeling technology 16.6.1.2. Low-temperature Deposition Manufacturing 16.6.1.3. Multiphase Jet Solidification 16.6.2. Photo polymerization 16.6.2.1. Stereo lithography 16.6.2.2. Continuous Liquid Interface Production 16.6.2.3. Two-Photon Polymerization 16.6.3. Laser Beam melting 16.6.3.1. Selective Laser Sintering 16.6.3.2. Selective laser melting 16.6.3.3. Direct Metal Laser Sintering 16.6.4. Electronic Beam Melting 16.6.5. Laminated Object Manufacturing 16.6.6. Three-Dimensional Printing 16.7. South America 3D Printing Medical Devices Market Value Share Analysis, By Application 16.8. South America 3D Printing Medical Devices Market Forecast, By Application 16.8.1. External wearable devices 16.8.2. Clinical study devices 16.8.3. Implants 16.8.4. Tissue engineering 16.9. South America 3D Printing Medical Devices Market Value Share Analysis, By End User 16.10. South America 3D Printing Medical Devices Market Forecast, By End User 16.10.1. Medical and surgical centers 16.10.2. Pharma and biotech companies 16.10.3. Academic institutions 16.11. South America 3D Printing Medical Devices Market Value Share Analysis, by Country 16.12. South America 3D Printing Medical Devices Market Forecast, by Country 16.12.1. Brazil 16.12.2. Mexico 16.12.3. Rest of South America 16.13. South America 3D Printing Medical Devices Market Analysis, by Country 16.14. Brazil 3D Printing Medical Devices Market Forecast, By Component 16.14.1. System/Device 16.14.2. Materials 16.14.3. Software & Services 16.15. Brazil 3D Printing Medical Devices Market Forecast, By Technology 16.15.1. Droplet Deposition 16.15.1.1. Fused deposition modeling technology 16.15.1.2. Low-temperature Deposition Manufacturing 16.15.1.3. Multiphase Jet Solidification 16.15.2. Photo polymerization 16.15.2.1. Stereo lithography 16.15.2.2. Continuous Liquid Interface Production 16.15.2.3. Two-Photon Polymerization 16.15.3. Laser Beam melting 16.15.3.1. Selective Laser Sintering 16.15.3.2. Selective laser melting 16.15.3.3. Direct Metal Laser Sintering 16.15.4. Electronic Beam Melting 16.15.5. Laminated Object Manufacturing 16.15.6. Three-Dimensional Printing 16.16. Brazil 3D Printing Medical Devices Market Forecast, By Application 16.16.1. External wearable devices 16.16.2. Clinical study devices 16.16.3. Implants 16.16.4. Tissue engineering 16.17. Brazil 3D Printing Medical Devices Market Forecast, By End User 16.17.1. Medical and surgical centers 16.17.2. Pharma and biotech companies 16.17.3. Academic institutions 16.18. Mexico 3D Printing Medical Devices Market Forecast, By Component 16.18.1. System/Device 16.18.2. Materials 16.18.3. Software & Services 16.19. Mexico 3D Printing Medical Devices Market Forecast, By Technology 16.19.1. Droplet Deposition 16.19.1.1. Fused deposition modeling technology 16.19.1.2. Low-temperature Deposition Manufacturing 16.19.1.3. Multiphase Jet Solidification 16.19.2. Photo polymerization 16.19.2.1. Stereo lithography 16.19.2.2. Continuous Liquid Interface Production 16.19.2.3. Two-Photon Polymerization 16.19.3. Laser Beam melting 16.19.3.1. Selective Laser Sintering 16.19.3.2. Selective laser melting 16.19.3.3. Direct Metal Laser Sintering 16.19.4. Electronic Beam Melting 16.19.5. Laminated Object Manufacturing 16.19.6. Three-Dimensional Printing 16.20. Mexico 3D Printing Medical Devices Market Forecast, By Application 16.20.1. External wearable devices 16.20.2. Clinical study devices 16.20.3. Implants 16.20.4. Tissue engineering 16.21. Mexico 3D Printing Medical Devices Market Forecast, By End User 16.21.1. Medical and surgical centers 16.21.2. Pharma and biotech companies 16.21.3. Academic institutions 16.22. Rest of South America 3D Printing Medical Devices Market Forecast, By Component 16.22.1. System/Device 16.22.2. Materials 16.22.3. Software & Services 16.23. Rest of South America 3D Printing Medical Devices Market Forecast, By Technology 16.23.1. Droplet Deposition 16.23.1.1. Fused deposition modeling technology 16.23.1.2. Low-temperature Deposition Manufacturing 16.23.1.3. Multiphase Jet Solidification 16.23.2. Photo polymerization 16.23.2.1. Stereo lithography 16.23.2.2. Continuous Liquid Interface Production 16.23.2.3. Two-Photon Polymerization 16.23.3. Laser Beam melting 16.23.3.1. Selective Laser Sintering 16.23.3.2. Selective laser melting 16.23.3.3. Direct Metal Laser Sintering 16.23.4. Electronic Beam Melting 16.23.5. Laminated Object Manufacturing 16.23.6. Three-Dimensional Printing 16.24. Rest of South America 3D Printing Medical Devices Market Forecast, By Application 16.24.1. External wearable devices 16.24.2. Clinical study devices 16.24.3. Implants 16.24.4. Tissue engineering 16.25. Rest of South America 3D Printing Medical Devices Market Forecast, By End User 16.25.1. Medical and surgical centers 16.25.2. Pharma and biotech companies 16.25.3. Academic institutions 16.26. South America 3D Printing Medical Devices Market Attractiveness Analysis 16.26.1. By Component 16.26.2. By Technology 16.26.3. By Application 16.26.4. By End User 16.27. PEST Analysis 16.28. Key Trends 16.29. Key Development 17. Company Profiles 17.1. Market Share Analysis, by Company 17.2. Competition Matrix 17.2.1. Competitive Benchmarking of key players by price, presence, market share, Applications and R&D investment 17.2.2. New Product Launches and Product Enhancements 17.2.3. Market Consolidation 17.2.3.1. M&A by Regions, Investment and Applications 17.2.3.2. M&A Key Players, Forward Integration and Backward 17.2.3.3. Integration 17.3. Company Profiles: Key Players 17.3.1. 3D Systems Corporation 17.3.1.1. Company Overview 17.3.1.2. Financial Overview 17.3.1.3. Product Portfolio 17.3.1.4. Business Strategy 17.3.1.5. Recent Developments 17.3.1.6. Company Footprint 17.3.2. EnvisonTec 17.3.3. Stratasys Ltd. 17.3.4. Arcam AB 17.3.5. Cyfuse Biomedical KK 17.3.6. Organovo Holdings 17.3.7. EOS GmbH 17.3.8. FabRx Ltd. 17.3.9. Materialise N.V. 17.3.10. Concept Laser 17.3.11. SLM Solutions Group AG 17.3.12. Oxford Performance Materials, Inc. 17.3.13. Bio3D Technologies 17.3.14. Laser GmbH 17.3.15. Renishawplc 17.3.16. Prodways Group 17.3.17. 3T RPD Ltd. 17.3.18. Anatmics Pvt. Ltd. 17.3.19. Biomedical Modeling Inc. 17.3.20. Carbon Inc 18. Primary Key Insights
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