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Europe 3D Cell Culture Market, Competition, Forecast & Opportunities, 2018-2028

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    Report

  • 130 Pages
  • October 2023
  • Region: Europe
  • TechSci Research
  • ID: 5024011
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Europe 3D Cell Culture Market has valued at USD 376.96 Million in 2022 and is anticipated to project impressive growth in the forecast period with a CAGR of 7.55% through 2028. 3D cell culture represents an artificially-created environment where biological cells can freely interact with their surroundings in all three dimensions. Cells grown in this three-dimensional environment exhibit similar characteristics and behavior to those found in living organisms. This technique enables cells to grow in their natural environment, simulating an in vivo condition. Unlike 2D environments, 3D cell culture allows cells to grow in all directions within an artificially created setting.

Bioreactors and small capsules are commonly utilized to cultivate these three-dimensional environments for cell growth. In this environment, cells differentiate and migrate in response to their three-dimensional surroundings, facilitating tissue maturation and organization. This methodology finds extensive application in pharmaceutical and biotechnology companies, as well as academic institutions and research labs. 3D cultures are particularly valuable in research that necessitates in vivo model systems to investigate the effects of foreign substances on bodily tissues and organs. They accurately recreate the normal morphology and microarchitecture of organs, thanks to their biomimetic tissue constructions. As a result, a considerable number of research entities have adopted 3-dimensional cell culture techniques. Furthermore, the use of 3D tissue-engineered models has emerged as a novel approach to conventional methods for treating Covid-19, cancer, and other clinical illnesses.

Key Market Drivers

Increasing Focus on Precision Medicine

The increasing focus on precision medicine is anticipated to have a profound impact on the growth of the 3D cell culture market within the estimated timeframe. As researchers delve deeper into the potential of 3D cultures, particularly organoid cultures, new possibilities are emerging for the development of personalized therapies tailored to each patient's unique needs. For instance, considering the inherent variations in cancer cells due to mutations among different individuals, the ability to grow small tumor explants from individual patients and evaluate their response to treatment has been employed in numerous studies to identify novel drugs. This approach allows researchers to gain insights into the specific characteristics of a patient's tumor and design targeted therapies accordingly.

In the realm of respiratory medicine, researchers have successfully cultivated organoids from cystic fibrosis patients to determine their responsiveness to the drug ivacaftor. Encouragingly, the organoid cultures accurately predicted the subsequent positive responses observed in the patients, highlighting the potential of this approach in guiding treatment decisions. Similar findings have been observed in cancer research, where patient-derived pancreatic cancer tumoroids have exhibited a correlation in drug sensitivity with the original tumors. This exciting development opens up possibilities for tailoring treatment approaches on an individual basis for various diseases, potentially leading to improved patient outcomes.

Considering the versatility of organoid cultures and their ability to be generated from adult tissues, this approach holds significant promise in the field of precision medicine. By enabling researchers to better understand the intricacies of diseases and develop targeted therapies, the utilization of 3D cell cultures is expected to shape the future of medicine. The growing prominence of precision medicine, coupled with the advancements in 3D cell culture technologies, is poised to drive the growth of the 3D cell culture market during the forecast period. The ability to develop personalized therapies based on patient-specific characteristics is revolutionizing the field of medicine and has the potential to transform the way we approach and treat diseases.

Rise in Drug Development

The rise in drug development activities in Europe is driving an increasing demand for 3D cell culture technologies. As the pharmaceutical and biotechnology industries continue to expand their efforts in discovering and developing novel therapeutic agents, the limitations of traditional 2D cell cultures have become increasingly apparent. 3D cell culture systems, which more closely mimic the physiological environment of human tissues and organs, have emerged as invaluable tools for drug screening, toxicity testing, and understanding disease mechanisms.

Additionally, the demand for 3D cell culture is fueled by the growing interest in personalized medicine. Researchers are increasingly looking to create patient-specific models using 3D culture systems to develop customized treatment strategies and gain insights into individualized drug responses. This approach has the potential to revolutionize healthcare by tailoring therapies to the unique genetic and physiological characteristics of patients. The regulatory agencies in Europe have recognized the importance of 3D cell culture in improving the safety and efficacy assessment of pharmaceuticals. This recognition has led to an increased adoption of 3D cell culture in drug development, as it aligns with the evolving regulatory landscape.

Rising Burden of Chronic Diseases

The escalating burden of chronic diseases in Europe is undeniably driving an increased demand for 3D cell culture technologies, as these innovative systems hold immense promise in advancing our understanding of these complex health conditions and expediting the development of novel therapies. Chronic diseases, including cancer, cardiovascular disorders, diabetes, and neurodegenerative conditions, are a growing concern in Europe due to factors like an aging population, sedentary lifestyles, and changing dietary habits. 3D cell culture systems offer a transformative approach to studying the underlying mechanisms of these diseases by providing a more physiologically relevant environment compared to traditional 2D cultures.

Researchers are increasingly turning to 3D cell culture models to better mimic the intricate microenvironments of human tissues and organs. This enables them to study disease progression, cellular interactions, and drug responses with greater accuracy, ultimately leading to more effective therapeutic strategies. For instance, 3D cell culture systems allow scientists to investigate the behavior of cancer cells within a 3D context, offering insights into tumor growth and response to potential treatments that cannot be replicated in 2D settings. Moreover, the demand for 3D cell culture is augmented by the need for personalized medicine in the face of rising chronic diseases. By using patient-specific cells and creating 3D models that mimic the individual's disease state, researchers can tailor treatments and develop precision therapies, ultimately improving patient outcomes.

Increasing Adoption Of 3D Cell Cultures in Cancer Research

The increasing adoption of 3D cell cultures in cancer research is driving a substantial demand for this technology in Europe. Cancer remains one of the most pressing healthcare challenges worldwide, and Europe is no exception, with a rising incidence of various malignancies. Researchers and oncologists are increasingly turning to 3D cell culture models due to their ability to closely mimic the complex microenvironment of tumors, offering valuable insights into cancer biology and therapeutic development.

In cancer research, 3D cell cultures provide a more accurate representation of in vivo tumor conditions than traditional 2D models. They allow scientists to study key aspects of cancer, such as tumor growth, invasion, angiogenesis, and metastasis, with greater fidelity to what occurs within the human body. This improved relevance is instrumental in identifying potential drug candidates and understanding drug resistance mechanisms, leading to more effective cancer treatments. The demand for 3D cell cultures is further bolstered by the emergence of precision medicine in oncology. Researchers can create patient-specific 3D models using cancer cells derived from individual patients, enabling personalized drug screening and the development of tailored treatment regimens. This approach holds the promise of improving patient outcomes and reducing the burden of adverse side effects.

Key Market Challenges

Difficulties in Assay Development for Cells In 3D Environments

The majority of cell-based assays have traditionally relied on 2D monolayers in conventional cell culture settings. As researchers transition to using 3D cell spheroid models, the need for assay conditions optimization becomes evident. Adapting assays to 3D environments presents unique challenges, such as the effective penetration and lysis of spheroids by reagents, as well as concerns about signal quenching when dealing with larger spheroids.

To address these challenges, various potential solutions have been explored. One approach is the utilization of stronger detergents specifically reformulated for use in 3D cultures, which can enhance the lysis process. Additionally, extending incubation times allows for thorough and effective addressing of these obstacles. Successfully optimizing assays for 3D culture systems is of paramount importance, as it can significantly impact market growth during the forecast period. By addressing the specific challenges associated with 3D cell cultures, researchers can unlock the full potential of these models and pave the way for advancements in biomedical research and drug discovery.

Dearth of Consistency in Products Being Developed Through 3d Cell Culture

The use of scaffolds in three-dimensional cell cultures has greatly broadened the horizons of research possibilities. However, one of the challenges researchers faces is the variability that arises from the presence of different growth factors in scaffolds across different batches. This variability poses difficulties in biological research that focuses on studying signalling pathways and conducting pharmacological studies. Interestingly, despite this variability, cells grown on scaffolds with low growth factors exhibited phenotypes comparable to those grown on scaffolds with high growth factors. However, it is worth noting that the proliferation rate of these cells remained consistently high, highlighting the robust nature of the cell cultures on scaffolds.

Key Market Trends

Introduction of New Products

The introduction of new products, coupled with advancements in technology and increased investment in research and development, is expected to have a significant impact on the Europe 3D Cell Culture Market. These developments are driving the creation of innovative products that not only offer improved performance and efficiency but also provide more accurate biological models. As a result, the outcomes of drug discovery and toxicity testing processes are being enhanced. This increased accuracy and effectiveness are anticipated to fuel the demand for 3D cell culture products, thereby fostering substantial market growth in the European region.

Increasing collaborations & partnerships among key players

The increasing collaborations and partnerships among various organizations for the development and advancement of 3D cell cultures are anticipated to create substantial growth opportunities for the market in the years to come. These collaborations aim to foster innovation and drive the evolution of 3D cell culture technologies, enabling researchers to explore new frontiers in cell biology.

For instance, in June 2020, Lonza, a global leader in cell culture solutions, partnered with the Swedish company CELLINK to provide a comprehensive solution for 3-dimensional (3D) bioprinting. This strategic alliance brings together Lonza's expertise in cell culture media and reagents with CELLINK's cutting-edge bioprinting technology. The goal is to enhance and facilitate complete 3D cell culture workflows, enabling researchers to create more complex and physiologically relevant tissue models.

Furthermore, in April 2022, Manchester BIOGEL, a pioneer in peptide hydrogel technology, joined forces with Cell Guidance Systems Ltd. to introduce PODS-PeptiGels, an innovative kit that integrates the advantages of two established cell culture technologies. The kit combines synthetic peptide hydrogels, known as PeptiGels, with a collection of constant-release growth factors called PODS. This collaboration aims to offer a reliable and flexible platform for 3D cell culture by leveraging the unique features of both technologies. The resulting PODS-PeptiGels kit provides researchers with a reproducible and highly adaptable environment for conducting their 3D cell culture experiments, enabling them to achieve more accurate and physiologically relevant results.

These collaborative efforts not only demonstrate the commitment of industry leaders to advancing 3D cell culture technologies but also pave the way for the optimization and expansion of access to these advanced tools. By combining expertise and resources, these partnerships accelerate the translation of scientific discoveries into practical applications, driving the growth and adoption of 3D cell cultures in various fields such as drug discovery, regenerative medicine, and tissue engineering. The increasing collaborations and partnerships in the field of 3D cell cultures promise to revolutionize the way researchers study and understand cellular behavior. By harnessing the power of collective knowledge and expertise, these collaborative endeavors are poised to shape the future of cell biology and accelerate the growth of the market in the years to come.

Segmental Insights

Product Insights

Based on the product, the scaffold-based 3D cell cultures segment held the largest market share in 2022. Scaffold-based cell culture involves providing support to cells in all dimensions using either an artificial structure or a hydrogel, which is a polymer network. Hydrogels, recognized for their high-water content (up to 90%), can consist of either animal-derived extracellular matrix (ECM) proteins or synthetic formulations that are free from animal components.

The purpose of embedding cells in hydrogels is to emulate the natural extracellular matrix found in living organisms. Alternatively, "hard" scaffolds can be fabricated using specialized culture ware that possesses fibrous or sponge-like structures. These scaffolds are typically composed of biodegradable materials such as optically transparent polystyrene or polycaprolactone, enabling optimized imaging. Although these engineered supports may differ from the in vivo ECM, they offer advantages such as improved reproducibility and simplified cell retrieval from the culture. These factors are expected to contribute to the segmental growth of the market during the forecast period.

End User Insights

Based on end user, the biotechnology and pharmaceutical industries segment accounted for a substantial revenue share of 48%. This can be attributed to the significant advantages offered by 3D cell culture, which provides a more realistic representation of cell interactions, division, and morphology. By closely resembling the natural cellular environment, 3D cell culture systems enable gene expression and morphology to be more representative of the human body. One key advantage of 3D cell culture is the creation of environmental niches and microenvironments. Within these specialized settings, cells experience varying levels of oxygen, nutrients, metabolites, and signaling molecules. This dynamic environment stands in contrast to traditional 2D cell culture, where cells have unrestricted and equal access to these factors. The ability to mimic these complex conditions in 3D cell culture systems drives the growth and innovation within the biotechnology and pharmaceutical industries segment. By providing a more accurate representation of the human body's cellular environment, 3D cell culture systems hold the potential to revolutionize drug discovery, tissue engineering, and personalized medicine. This transformative impact further solidifies the importance of the biotechnology and pharmaceutical industries in shaping the future of healthcare.

Country Insights

Germany is expected to emerge as a dominant force in the European 3D cell culture market, primarily driven by its substantial investments in the biotechnology and pharmaceutical sector. The country's strong foothold in this market can also be attributed to the presence of well-established and globally renowned research institutions, fostering a culture of innovation and excellence. Furthermore, Germany's robust healthcare infrastructure and unwavering governmental support for scientific research contribute to its competitive advantage in this field. With a rich ecosystem that combines cutting-edge technology, top-tier expertise, and a conducive environment for growth, Germany is poised to lead the way in revolutionizing the field of 3D cell culture in Europe and beyond.

Report Scope:

In this report, the Europe 3D Cell Culture Market has been segmented into the following categories, in addition to the industry trends which have also been detailed below:

Europe 3D Cell Culture Market, By Product:

  • Scaffold-Based 3D Cell Cultures
  • Scaffold-Free 3D Cell Cultures
  • Microfluidics
  • Magnetic Levitation

Europe 3D Cell Culture Market, By End User:

  • Pharmaceutical & Biotechnology Companies
  • Research Institutes
  • Cosmetics Industry
  • Others

Europe 3D Cell Culture Market, By Application:

  • Cancer & Stem Cell Research
  • Drug Discovery & Toxicology Testing
  • Tissue Engineering & Regenerative Medicine

Europe 3D Cell Culture Market, By Country:

  • Germany
  • France
  • United Kingdom
  • Italy
  • Spain
  • Russia
  • Poland

Competitive Landscape

Company Profiles: Detailed analysis of the major companies present in the Europe 3D Cell Culture Market.

Available Customizations:

Europe 3D Cell Culture Market report with the given market data, the publisher offers customizations according to a company's specific needs.


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Table of Contents

1. Product Overview
1.1. Market Definition
1.2. Scope of the Market
1.2.1. Markets Covered
1.2.2. Years Considered for Study
1.2.3. Key Market Segmentations
2. Research Methodology
2.1. Objective of the Study
2.2. Baseline Methodology
2.3. Key Industry Partners
2.4. Major Association and Secondary Sources
2.5. Forecasting Methodology
2.6. Data Triangulation & Validations
2.7. Assumptions and Limitations
3. Executive Summary
3.1. Overview of the Market
3.2. Overview of Key Market Segmentations
3.3. Overview of Key Market Players
3.4. Overview of Key Regions/Countries
3.5. Overview of Market Drivers, Challenges, Trends
4. Voice of Customer
5. Europe 3D Cell Culture Market Outlook
5.1. Market Size & Forecast
5.1.1. By Value
5.2. Market Share & Forecast
5.2.1. By Product (Scaffold-Based 3D Cell Cultures, Scaffold-Free 3D Cell Cultures, Microfluidics, Magnetic Levitation)
5.2.2. By End User (Pharmaceutical & Biotechnology Companies, Research Institutes, Cosmetics Industry, Others)
5.2.3. By Application (Cancer & Stem Cell Research, Drug Discovery & Toxicology Testing, Tissue Engineering & Regenerative Medicine)
5.2.4. By Country
5.2.5. By Company (2022)
5.3. Market Map
6. Country Analysis
6.1. Germany 3D Cell Culture Market Outlook
6.1.1. Market Size & Forecast
6.1.1.1. By Value
6.1.2. Market Share & Forecast
6.1.2.1. By Product
6.1.2.2. By End User
6.1.2.3. By Application
6.2. France 3D Cell Culture Market Outlook
6.2.1. Market Size & Forecast
6.2.1.1. By Value
6.2.2. Market Share & Forecast
6.2.2.1. By Product
6.2.2.2. By End User
6.2.2.3. By Application
6.3. United Kingdom 3D Cell Culture Market Outlook
6.3.1. Market Size & Forecast
6.3.1.1. By Value
6.3.2. Market Share & Forecast
6.3.2.1. By Product
6.3.2.2. By End User
6.3.2.3. By Application
6.4. Italy 3D Cell Culture Market Outlook
6.4.1. Market Size & Forecast
6.4.1.1. By Value
6.4.2. Market Share & Forecast
6.4.2.1. By Product
6.4.2.2. By End User
6.4.2.3. By Application
6.5. Spain 3D Cell Culture Market Outlook
6.5.1. Market Size & Forecast
6.5.1.1. By Value
6.5.2. Market Share & Forecast
6.5.2.1. By Product
6.5.2.2. By End User
6.5.2.3. By Application
6.6. Russia 3D Cell Culture Market Outlook
6.6.1. Market Size & Forecast
6.6.1.1. By Value
6.6.2. Market Share & Forecast
6.6.2.1. By Product
6.6.2.2. By End User
6.6.2.3. By Application
6.7. Poland 3D Cell Culture Market Outlook
6.7.1. Market Size & Forecast
6.7.1.1. By Value
6.7.2. Market Share & Forecast
6.7.2.1. By Product
6.7.2.2. By End User
6.7.2.3. By Application
7. Market Dynamics
7.1. Drivers
7.2. Challenges
8. Market Trends & Developments
8.1. Recent Development
8.2. Mergers & Acquisitions
8.3. Product Launches
9. Europe 3D Cell Culture Market: SWOT Analysis
10. Porter’s Five Forces Analysis
10.1. Competition in the Industry
10.2. Potential of New Entrants
10.3. Power of Suppliers
10.4. Power of Customers
10.5. Threat of Substitute Products
11. Competitive Landscape
11.1. Business Overview
11.2. Service Offerings
11.3. Recent Developments
11.4. Key Personnel
11.5. SWOT Analysis
11.5.1. Tecan Trading AG
11.5.2. Merck KGaA
11.5.3. Promocell GmbH
11.5.4. Lonza Group
11.5.5. Tecan Trading AG
11.5.6. CN Bio Innovations Ltd.
11.5.7. TissUse GmbH
11.5.8. Cellendes GmbH
11.5.9. Greiner Bio-one International GmbH
11.5.10. Advanced BioMatrix, Inc.
12. Strategic Recommendations
About the Publisher & Disclaimer

Companies Mentioned (Partial List)

A selection of companies mentioned in this report includes, but is not limited to:

  • Tecan Trading AG
  • Merck KGaA
  • Promocell GmbH
  • Lonza Group
  • Tecan Trading AG
  • CN Bio Innovations Ltd.
  • TissUse GmbH
  • Cellendes GmbH
  • Greiner Bio-one International GmbH
  • Advanced BioMatrix, Inc.

Table Information