Poland 3D Printing Medical Devices Market Report 2022 to 2030

Poland 3D Printing Medical Devices Market Analysis

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Poland 3D Printing Medical Device Market is expected to witness growth from $17 Mn in 2022 to $59 Mn in 2030 with a CAGR of 16.75% for the forecasted year 2022-2030. In Poland, Patients need medical devices that are specifically designed for their individual anatomical demands and medical requirements. The demand for 3D printing medical devices in Poland is being driven by manufacturers ability to create customised medical devices quickly and affordably. The market is segmented by application, by technology and by end user. Some key players in this market include: Braster S.A, Skamex, Stryker, Stratasys, GE Additive and Prodways Group.

ID: IN10PLMD002 CATEGORY: Medical Devices GEOGRAPHY: Poland AUTHOR: Jigyasu Bhandari

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Poland 3D Printing Medical Devices Market Executive Summary

The Poland 3D Printing Medical Devices Market size is at around $17 Mn in 2022 and is projected to reach $59 Mn in 2030, exhibiting a CAGR of 16.75% during the forecast period. In the European Union, Poland has some of the lowest health expenditures (EU). Health expenditure in Poland is $1347.23 per person, or 6.3% of GDP, compared to the EU average of $3000, or 10.12% of GDP, in 2020. Less than the EU norm of 79%, 72% of expenses are paid for with public money. The relatively large out-of-pocket spending (22%) raises questions about accessibility. Despite falling from 23% in 2014 to 19% in 2023, Poland still has a greater rate of daily smokers among adults than the majority of other European Union (EU) nations.

In Poland, Anatomical models of patient-specific anatomy can be produced using 3D printing technology, giving surgeons the ability to plan operations beforehand and run through processes before operating on a patient. In the dentistry sector, 3D printing is also used to create dental prosthetics, implants, and aligners. Anatomical models for instruction are being created using 3D printing more and more in medical education. Students can learn about intricate anatomical structures and acquire practical experience by using these models. By removing the need for costly tooling and cutting down on waste, 3D printing can lower the cost of producing medical products. This might lead to medical equipment becoming more reasonably priced, which would be good for patients and medical professionals.

Poland 3D Printing Medical Device Market Analysis

Market Dynamics

Market Growth Drivers Analysis

In Poland, Patients need medical devices that are specifically designed for their individual anatomical demands and medical requirements. The demand for 3D printing medical devices in Poland is being driven by manufacturers ability to create customised medical devices quickly and affordably. When compared to traditional manufacturing methods, 3D printing might be more cost-effective for some medical devices, particularly those produced in small quantities. As a consequence, the market for 3D printed medical equipment is growing and more healthcare professionals are using 3D printing. With the advancement of new 3D printing methods and materials, the range of medical devices that can be produced using 3D printing has expanded. Manufacturers now have more chances to create innovative products that meet the needs of patients and healthcare workers.

Market Restraints

The Poland market for 3D printed medical devices has a sizable growth potential, but manufacturers may encounter a number of market barriers, such as regulatory obstacles, barriers to technology access, problems with quality control, issues with intellectual property, and reimbursement restrictions. Concerns about intellectual property theft are growing as 3D printing technology spreads. Medical devices, which are frequently covered by patents and other forms of intellectual property protection, are especially important in this regard.

Competitive Landscape

Key Players

Braster S.A (PL)
Skamex (PL)
Stratasys
GE Additive
Stryker
Prodways Group

Notable Recent Deals

2022: The Swedish additive manufacturing business, AddNorth, has acquired Spectrum Filaments, a 3D printing firm in Poland. One of the top producers of premium filaments for use in 3D printing uses, such as medical devices, is Spectrum Filaments. With the acquisition, AddNorth is now able to offer a wider range of devices and provide for its clients in the medical device sector.

Healthcare Policies and Regulatory Landscape

The Office for Registration of Medicinal Products (URPL), Medical Devices, and Biocidal Products, along with the Ministry of Health, oversee Poland's regulatory framework for 3D Printed medical devices. Before being sold in the Polish market, medical devices must adhere to stringent safety and efficacy standards. The Medical Devices Regulation (MDR) of the European Union, which went into force on May 26, 2021, has been implemented in Poland. Prior to being put on the market, the MDR mandates that all medical devices go through stringent conformity assessments to make sure they satisfy the requirements for safety and efficacy. The Poland government has created its own set of medical device regulations in addition to the MDR, which contains standards for the production, importation, and distribution of medical devices. The regulations outline the requirements for 3D-printed medical devices and demand that they be listed with the URPL before being offered for sale in the Poland market.

1. Executive Summary
1.1 Device Overview
1.2 Global Scenario
1.3 Country Overview
1.4 Healthcare Scenario in Country
1.5 Regulatory Landscape for Medical Device
1.6 Health Insurance Coverage in Country
1.7 Type of Medical Device
1.8 Recent Developments in the Country

2. Market Size and Forecasting
2.1 Market Size (With Excel and Methodology)
2.2 Market Segmentation (Check all Segments in Segmentation Section)

3. Market Dynamics
3.1 Market Drivers
3.2 Market Restraints

4. Competitive Landscape
4.1 Major Market Share

4.2 Key Company Profile (Check all Companies in the Summary Section)

4.2.1 Company
4.2.1.1 Overview
4.2.1.2 Product Applications and Services
4.2.1.3 Recent Developments
4.2.1.4 Partnerships Ecosystem
4.2.1.5 Financials (Based on Availability)

5. Reimbursement Scenario
5.1 Reimbursement Regulation
5.2 Reimbursement Process for Diagnosis
5.3 Reimbursement Process for Treatment

6. Methodology and Scope

3D Printing Medical Devices Market Segmentation

By Component (Revenue, USD Billion):

The 3D Printing Medical Devices market is divided into equipment, materials, and software & services depending on the component. In 2020, the market for 3D printed medical devices was dominated by software and services. During the forecast period, the cost-effectiveness, utility, uniformity, and accuracy provided by services for medical device 3D printing are anticipated to drive the segment's expansion.

Equipment
- 3D Printers
- 3D Bioprinters
Materials
Plastics
- Thermoplastics
- Photopolymers
Metals and Metal Alloys
Biomaterials
Ceramics
Paper
Wax
Other Materials
Services & Software

By Application (Revenue, USD Billion):

The market for 3D-printed medical devices is divided into wearable/implantable medical devices, other medical devices, standard prosthetics and implants, custom prosthetics and implants, tissue-engineered goods, surgical guides, and surgical tools based on the application. In 2020, the custom prosthetics and implants market sector held a greater market share. Biological materials (such skin and bones), plastics, ceramics, and metals are just a few of the materials that may be used to create highly customizable prosthetics and implants using 3D printing. The development of this market sector is anticipated to be fueled by 3D printing of custom implants, which is drawing in new investors and medical device businesses.

Surgical Guides
- Dental Guides
- Craniomaxillofacial Guides
- Orthopedic Guides
- Spinal Guides
Surgical Instruments
Surgical Fasteners
Scalpels
Retractors
Standard Prosthetics & Implants
Orthopedic Implants
Dental Prosthetics & Implants
Craniomaxillofacial Implants
Bone & Cartilage Scaffolds
Ligament & Tendon Scaffolds
Custom Prosthetics & Implants
Tissue-engineered Products
Hearing Aids
Wearable Medical Devices
Other Applications

By Technology (Revenue, USD Billion):

The market for 3D printing medical devices has been divided into various technological categories, including electron beam melting (EBM), laser beam melting (LBM), photopolymerization, droplet deposition or extrusion-based technologies, three-dimensional printing (3DP) or adhesion bonding, and others. The segment of these that accounted for the biggest market share in 2020 was laser beam melting (LBM). The significant market share of this sector is linked to the technology's expanding use in the dentistry sector and in the production of implants for minimally invasive surgery.

Laser Beam Melting
- Direct Metal Laser Sintering
- Selective Laser Sintering
- Selective Laser Melting
- LaserCUSING
Photopolymerization
Digital Light Processing
Stereolithography
Two-photon Polymerization
PolyJet 3D Printing
Fused Deposition Modeling
Multiphase Jet Solidification
Low-temperature Deposition Manufacturing
Microextrusion Bioprinting
Droplet Deposition/Extrusion-based Technologies
Electron Beam Melting
Three-dimensional Printing/Adhesion Bonding/Binder Jetting
Other Technologies

By End User (Revenue, USD Billion):

Hospitals and surgical centers, dentistry and orthopaedic clinics, academic institutions & research laboratories, pharma-biotech & medical device firms, and clinical research organizations make up the different end-user segments of the 3D printing medical devices market. The sector of hospitals and surgical centers held the biggest market share in 2020. The significant market share of this sector can be due to the increased uptake of cutting-edge medical technology by hospitals, the expansion of existing 3D printing facilities, and the rising affordability of 3D printing services.

Hospitals & Surgical Centers
Dental & Orthopedic Clinics
Academic Institutions & Research Laboratories
Pharma-Biotech & Medical Device Companies
Clinical Research Organizations

Methodology for Database Creation

Our database offers a comprehensive list of healthcare centers, meticulously curated to provide detailed information on a wide range of specialties and services. It includes top-tier hospitals, clinics, and diagnostic facilities across 30 countries and 24 specialties, ensuring users can find the healthcare services they need.

Additionally, we provide a comprehensive list of Key Opinion Leaders (KOLs) based on your requirements. Our curated list captures various crucial aspects of the KOLs, offering more than just general information. Whether you're looking to boost brand awareness, drive engagement, or launch a new product, our extensive list of KOLs ensures you have the right experts by your side. Covering 30 countries and 36 specialties, our database guarantees access to the best KOLs in the healthcare industry, supporting strategic decisions and enhancing your initiatives.

How Do We Get It?

Our database is created and maintained through a combination of secondary and primary research methodologies.

1. Secondary Research

With many years of experience in the healthcare field, we have our own rich proprietary data from various past projects. This historical data serves as the foundation for our database. Our continuous process of gathering data involves:

Analyzing historical proprietary data collected from multiple projects.
Regularly updating our existing data sets with new findings and trends.
Ensuring data consistency and accuracy through rigorous validation processes.

With extensive experience in the field, we have developed a proprietary GenAI-based technology that is uniquely tailored to our organization. This advanced technology enables us to scan a wide array of relevant information sources across the internet. Our data-gathering process includes:

Searching through academic conferences, published research, citations, and social media platforms
Collecting and compiling diverse data to build a comprehensive and detailed database
Continuously updating our database with new information to ensure its relevance and accuracy

2. Primary Research

To complement and validate our secondary data, we engage in primary research through local tie-ups and partnerships. This process involves:

Collaborating with local healthcare providers, hospitals, and clinics to gather real-time data.
Conducting surveys, interviews, and field studies to collect fresh data directly from the source.
Continuously refreshing our database to ensure that the information remains current and reliable.
Validating secondary data through cross-referencing with primary data to ensure accuracy and relevance.

Combining Secondary and Primary Research

By integrating both secondary and primary research methodologies, we ensure that our database is comprehensive, accurate, and up-to-date. The combined process involves:

Merging historical data from secondary research with real-time data from primary research.
Conducting thorough data validation and cleansing to remove inconsistencies and errors.
Organizing data into a structured format that is easily accessible and usable for various applications.
Continuously monitoring and updating the database to reflect the latest developments and trends in the healthcare field.

Through this meticulous process, we create a final database tailored to each region and domain within the healthcare industry. This approach ensures that our clients receive reliable and relevant data, empowering them to make informed decisions and drive innovation in their respective fields.