Single-Use Downstream Bioprocessing Technology Market, 2022-2035

Single-Use Downstream Bioprocessing Technology Market, 2022-2035

The biopharmaceutical industry has witnessed significant growth over the past few years. Till date, more than 620 biologics have already been approved by the USFDA , while 8,000 are under clinical evaluation. The increased number of approvals and ongoing clinical trials demonstrate the growing popularity of novel treatment options for a variety of ailments and diseases. As a result, several stakeholders have opted to modernize their conventional biomanufacturing technologies in order to cope up with the increasing demand for biologics and to reduce the cost and time involved in bioprocessing. One such example is the use of single-use technology for various upstream and downstream processes involved in biologics manufacturing. The use of single-use technologies in biopharmaceutical manufacturing has been steadily increasing over the years. Specifically, the adoption of single-use technology in downstream bioprocessing has witnessed a remarkable increase in the last few years. Single-use downstream technologies offer various advantages over the traditional stainless-steel technologies, such as reduction in CO2 emissions (by 35%), reduction in project lead time (by 8 months), removal of cleaning and sterilization expenditure throughout the development stage, increased productivity, less labor intensive, and low risk of contamination.4,5

Given the various benefits of single-use downstream bioprocessing technology and its increasing adoption, several companies have developed and launched their proprietary single-use products, such as single-use chromatography systems, single-use filtration systems, single-use sampling systems, single-use connectors and single-use centrifugation systems, for the faster production of finished and high-quality biologics intended for the treatment of a wide array of disease indications. In addition, some stakeholders have also taken initiatives to automate their single-use systems, by introducing several key features, such as visual data display, remote accessibility, data processing capability, built-in system control sensors, irradiation (gamma or x-ray), provision for alarms / alerts and input / output compatibility in order to make the equipment more user friendly. Driven by the increasing adoption of single-use technology and the ongoing efforts to enhance features and capabilities of various single-use equipment, the opportunity within this market is likely grow at a noteworthy pace over the coming years.

SCOPE OF THE REPORT

The “Single-Use Downstream Bioprocessing Technology Market by Type of Product (Single-use Chromatography Systems, Single-use Filtration Systems, Single-use Sampling Systems and Single-use Connectors), Scale of Operation (Preclinical / Clinical and Commercial) and Key Geographical Regions (North America, Europe, Asia-Pacific, Latin-America, Middle East and North Africa and Rest of the World): Industry Trends and Global Forecasts, 2022-2035” report features an extensive study of the current landscape and the likely future potential of single-use downstream bioprocessing technology and equipment developers, over the next 13 years. The study also features an in-depth analysis, highlighting the capabilities of various industry stakeholders engaged in this field. In addition to other elements, the study includes:

  • A detailed assessment of the market landscape of single-use chromatography systems based on a number of relevant parameters, such as product / device dimensions, flow rate, volume range, pressure, weight, mode of operation (batch, fed-batch and continuous), scale of operation (preclinical, clinical and commercial), key features (scalability, visual data display, remote accessibility, data processing capability, built-in system control sensors, I / O compatibility and provision for alarms / alerts)and application area (monoclonal antibody production, vaccine production, cell and gene therapy, therapeutic protein / hormone and others). In addition, it presents details on the companies developing single-use chromatography systems, highlighting their year of establishment, company size, and geographical location.
  • A detailed assessment of the market landscape of single-use filtration systems based on a number of relevant parameters, such as filter pore size, type of membrane construction material, type of connector used, maximum temperature, pressure range, type of filter (membrane, capsule, cartridge and cassette), scale of operation (preclinical, clinical and commercial), key features (sterilizability, irradiation (gamma or x-ray), easy organization and fast aseptic connectors) and application area (monoclonal antibody production, vaccine production, cell and gene therapy, therapeutic protein / hormone and others). In addition, it presents details on the companies developing single-use filtration systems, highlighting their year of establishment, company size, and geographical location.
  • A detailed assessment of the market landscape of single-use sampling systems, based on several relevant parameters, such as type of sampling unit (bag, bottle, tube-transfer and syringe), type of sterilizability (irradiation (gamma or x-ray) and autoclavability), key features (scalability and pre-assembled), volume range and tubing material. The chapter also presents details on the companies involved in the development of single-use sampling systems, based on their year of establishment, company size, and geographical location. In addition, the chapter presents overview of the overall market landscape of single-use centrifugation systems.
  • A detailed assessment of the market landscape of single-use connectors based on number of relevant parameters, such as type of valve / gender (male, female and genderless), pack size, operating temperature, termination size, material of construction and application area (fluid transfer, sampling, process piping). In addition, it presents details on the companies developing single-use connectors, highlighting their year of establishment, company size, and geographical location.
  • A detailed competitiveness analysis of single-use chromatography systems, single-use filtration systems, single-use sampling systems and single-use connectors, taking into consideration several relevant parameters. For single-use chromatography systems, the parameters taken into account include the product strength (key features, mode of operation, scale of operation, elution method compatibility and application area) and supplier strength (company size and years of experience). For single-use filtration systems, the parameters taken into account include the product applicability (connectors used, type of filter, scale of operation, key features and application area) and supplier strength (company size and years of experience). For single-use sampling systems, the parameters taken into account include the product strength (sterilizability and key features) and supplier strength (company size and years of experience). For single-use connectors, the parameters taken into account include the product strength (type of valve / gender, easy to use, application area) and supplier strength (company size and years of experience).
  • Tabulated profiles of the key players providing single-use downstream bioprocessing technologies, which are headquartered in North America, Europe and Asia-Pacific. Each profile includes an overview of the company, information on the financial performance (if available), service portfolio, product portfolio, recent developments, and an informed future outlook.
  • An in-depth analysis of various patents that have been filed / granted for single-use downstream bioprocessing technology, till December 2021, highlighting key trends associated with these patents, across type of patents, publication year, application year, issuing authorities involved, type of organizations, emerging focus area, patent age, CPC symbols, leading patent assignees (in terms of number of patents granted / filed), patent characteristics and geography. It also includes a detailed patent benchmarking and an insightful valuation analysis.
  • A detailed brand positioning analysis of the key industry players (including single-use chromatography system developers, single-use filtration system developers, single-use sampling system developers and single-use connector developers), highlighting the current perceptions regarding their proprietary products by taking into consideration several relevant aspects, such as experience of the manufacturer, number of products offered, product diversity, and number of patents published.
  • An informed estimate on the current and future demand for biologics and demand-supply scenario for biologics manufactured using single-use downstream bioprocessing technologies, for the period 2022-2035.
One of the key objectives of the report was to understand the primary growth drivers and estimate the future size of single-use downstream bioprocessing technology / equipment market. Based on multiple parameters, such as overall downstream bioprocessing equipment market, and share of single-use technology, we have provided an informed estimate of the evolution of the market for the period 2022-2035. Our year-wise projections of the current and future opportunity have further been segmented on the basis of scale of operation (preclinical / clinical and commercial), type of product (single-use chromatography systems, single-use filtration systems, single-use sampling systems and single-use connectors), and key geographical regions (North America, Europe, Asia-Pacific, Latin America, MENA and Rest of the World). In order to account for future uncertainties and to add robustness to our model, we have provided three forecast scenarios, namely conservative, base and optimistic scenarios, representing different tracks of the industry’s growth.

MARKET SEGMENTATIONS

Single-Use Downstream Bioprocessing Technology: Market Segmentations

Market Segments Details

Forecast Period
  • 2022 – 2035

Scale of Operation
  • Preclinical
  • Clinical
  • Commercial
Type of Equipment
  • Single-use Chromatography Systems
  • Single-use Filtration Systems
  • Single-use Sampling Systems
  • Single-use Connectors
Key Geographical Regions
  • North America
  • Europe
  • Asia-Pacific
  • MENA
  • Latin America and Rest of the World
Source: Roots Analysis

RESEARCH METHODOLOGY

The data presented in this report has been gathered via secondary and primary research. For all our projects, we conduct interviews with experts in the area (academia, industry, medical practice and other associations) to solicit their opinions on emerging trends in the market. This is primarily useful for us to draw out our own opinion on how the market will evolve across different regions and technology segments. Wherever possible, the available data has been checked for accuracy from multiple sources of information.

The secondary sources of information include:
  • Annual reports
  • Investor presentations
  • SEC filings
  • Industry databases
  • News releases from company websites
  • Government policy documents
  • Industry analysts’ views
All actual figures have been sourced and analyzed from publicly available information forums and primary research discussions. Financial figures mentioned in this report are in USD, unless otherwise specified.

KEY QUESTIONS ANSWERED
  • Who are the leading players that offer single-use downstream bioprocessing technologies?
  • What are the different application areas where single-use downstream bioprocessing technologies can be employed?
  • In which regions, majority of the single-use downstream bioprocessing technology are developers located?
  • What is the relative competitiveness of different single-use downstream bioprocessing equipment?
  • How has the intellectual property landscape of single-use downstream bioprocessing technologies, evolved over the years?
  • What is the current demand and supply of biologics manufactured using single-use downstream bioprocessing technology?
  • How is the current and future opportunity likely to be distributed across key market segments?
CHAPTER OUTLINES

Chapter 2 is an executive summary of the key insights captured in our research. It offers a high-level view on the current state of the single-use downstream bioprocessing technology market and its likely evolution in the short to mid-term and long term.

Chapter 3 provides a general introduction to bioprocessing industry, covering details related to the current trends in the domain. The chapter provides difference between the stainless-steel technology and single-use technology. In addition, it also provides details on different types of single-use equipment. It emphasizes on various advantages and key challenges associated with the single-use technologies. Further, it discusses future perspectives of the single-use downstream bioprocessing technology.

Chapter 4 provides a detailed assessment of the overall market landscape of single-use chromatography systems based on a number of relevant parameters, such as product / device dimensions, flow rate, volume range, pressure, weight, mode of operation (batch, fed-batch and continuous), scale of operation (preclinical, clinical and commercial), key features (scalability, visual data display, remote accessibility, data processing capability, built-in system control sensors, I / O compatibility and provision for alarms / alerts) and application area (monoclonal antibody production, vaccine production, cell and gene therapy, therapeutic protein / hormone and others). In addition, it presents details on the companies developing single-use chromatography systems, highlighting their year of establishment, company size, and geographical location.

Chapter 5 provides a detailed assessment of the overall market landscape of single-use filtration systems based on a number of relevant parameters, such as filter pore size, type of membrane construction material, type of connector used, maximum temperature, pressure range, type of filter (membrane, capsule, cartridge and cassette), scale of operation (preclinical, clinical and commercial), key features (sterilizability, irradiation (gamma or x-ray), easy organization and fast aseptic connectors) and application area (monoclonal antibody production, vaccine production, cell and gene therapy, therapeutic protein / hormone and others). In addition, it presents details on the companies developing single-use filtration systems, highlighting their year of establishment, company size, and geographical location.

Chapter 6 provides a detailed assessment of the overall market landscape of single-use sampling systems, based on several relevant parameters, such as type of sampling units (bag, bottle, tube-transfer and syringe), sterilizability (irradiation (gamma or x-ray) and autoclavability), key features (scalability and pre-assembled), maximum volume range and tubing material. The chapter also presents details on the companies involved in the development of single-use sampling systems, based on their year of establishment, company size, and geographical location. In addition, the chapter presents overview of the overall market landscape of single-use centrifugation systems.

Chapter 7 provides a detailed assessment of the overall market landscape of single-use connectors based on a number of relevant parameters, such as type of valve / gender (male, female and genderless), pack size, operating temperature, termination size, material of construction and application area (fluid transfer, sampling, process piping). In addition, the chapter presents details on the companies involved in the development of single-use connectors, including information on their year of establishment, company size, and geographical location.

Chapter 8 features a detailed competitiveness analysis of single-use chromatography systems, single-use filtration systems, single-use sampling systems and single-use connectors, taking into consideration several relevant parameters. For single-use chromatography systems, the parameters taken into account include the product strength (key features, mode of operation, scale of operation, elution method compatibility and application area) and supplier strength (company size and years of experience). For single-use filtration systems, the parameters taken into account include the product applicability (connectors used, type of filter, scale of operation, key features and application area) and supplier strength (company size and years of experience). For single-use sampling systems, the parameters taken into account include the product strength (sterilizability and key features) and supplier strength (company size and years of experience). For single-use connectors, the parameters taken into account include the product strength (type of valve / gender, easy to use, application area) and supplier strength (company size and years of experience).

Chapter 9 features tabulated profiles of the key players providing single-use downstream bioprocessing technologies, which are headquartered in North America. Each profile includes an overview of the company, information on the financial performance (if available), service portfolio, product portfolio, recent developments, and an informed future outlook.

Chapter 10 features tabulated profiles of the key players providing single-use downstream bioprocessing technologies, which are headquartered in Europe and Asia-Pacific. Each profile includes an overview of the company, information on the financial performance (if available), service portfolio, product portfolio, recent developments, and an informed future outlook.

Chapter 11 presents an in-depth analysis of various patents that have been filed / granted for single-use downstream bioprocessing technology, till December 2021, highlighting key trends associated with these patents, across type of patents, publication year, application year, issuing authorities involved, type of organizations, emerging focus area, patent age, CPC symbols, leading patent assignees (in terms of number of patents granted / filed), patent characteristics and geography. It also includes a detailed patent benchmarking and an insightful valuation analysis.

Chapter 12 provides a detailed brand positioning analysis of the key industry players (including single-use chromatography system developers, single-use filtration system developers, single-use sampling system developers and single-use connector developers), highlighting the current perceptions regarding their proprietary products by taking into consideration several relevant aspects, such as experience of the manufacturer, number of products offered, product diversity, and number of patents published.

Chapter 13 provides an informed estimate on the current and future demand for biologics and demand-supply scenario for biologics manufactured using single-use downstream bioprocessing technologies, for the period 2022-2035.

Chapter 14 features a comprehensive market forecast analysis, highlighting the future potential of the market till 2035, based on multiple parameters, such as overall downstream bioprocessing equipment market, and share of single-use technology. It includes an informed estimate of the evolution of the market for the period 2022-2035. We have segregated the current and future opportunity have further been segmented on the basis of scale of operation (preclinical / clinical and commercial), type of product (single-use chromatography systems, single-use filtration systems, single-use sampling systems and single-use connectors), and key geographical regions (North America, Europe, Asia-Pacific, Latin America, MENA and Rest of the World).It is worth mentioning that we adopted a top-down approach for this analysis, backing our claims with relevant datapoints and credible inputs from primary research.

Chapter 15 is the summary of the overall report, which presents insights on the contemporary market trends and the likely evolution of the single-use downstream bioprocessing market.

Chapter 16 is an appendix, which provides tabulated data and numbers for all the figures provided in the report.

Chapter 17 is an appendix, which contains the list of companies and organizations mentioned in the report.


1. PREFACE
1.1. Overview
1.2. Scope of the Report
1.3. Research Methodology
1.4. Key Questions Answered
1.5. Chapter Outlines
2. EXECUTIVE SUMMARY
3. INTRODUCTION
3.1. Chapter Overview
3.2. Overview of Single-use Downstream Bioprocessing Technology
3.3. Type of Single-use Downstream Bioprocessing Technology
3.4. Difference between Conventional and Emerging Downstream Bioprocessing Technology
3.5. Advantages of Single-Use Downstream Bioprocessing Technology
3.6. Applications of Single-Use Downstream Bioprocessing Technology
3.7. Key Challenges Associated with Single-use Downstream Bioprocessing Technology
3.8. Future Perspective
4. MARKET LANDSCAPE: SINGLE-USE CHROMATOGRAPHY SYSTEMS
4.1. Chapter Overview
4.2. Single-use Chromatography Systems: List of Products
4.2.1. Analysis by Product / Device Dimensions (cm)
4.2.2. Analysis by Flow Rate (L/min)
4.2.3. Analysis by Volume Range (L)
4.2.4. Analysis by Working Pressure (Bar)
4.2.5. Analysis by Mode of Operation
4.2.6. Analysis by Weight (Kg)
4.2.7. Analysis by Key Feature(s)
4.2.8. Analysis by Scale of Operation
4.2.9 Analysis by Application Area
4.3. Single-use Chromatography Systems: Developer Landscape
4.3.1. Analysis by Year of Establishment
4.3.2. Analysis by Company Size
4.3.3. Analysis by Location of Headquarters
4.3.4. Leading Developers: Analysis by Number of Single-use Chromatography Systems
5. MARKET LANDSCAPE: SINGLE-USE FILTRATION SYSTEMS
5.1. Chapter Overview
5.2. Single-use Filtration Systems: List of Products
5.2.1. Analysis by Filter Pore Size (µm)
5.2.2. Analysis by Type of Membrane Construction Material
5.2.3. Analysis by Type of Connector Used
5.2.4. Analysis by Maximum Temperature (°C)
5.2.5. Analysis by Working Pressure Range (Bar)
5.2.6. Analysis by Type of Filter
5.2.7. Analysis by Scale of Operation
5.2.8. Analysis by Key Feature(s)
5.2.9. Analysis by Application Area
5.3. Single-use Filtration Systems: Developer Landscape
5.3.1. Analysis by Year of Establishment
5.3.2. Analysis by Company Size
5.3.3. Analysis by Location of Headquarters
5.3.4. Leading Developers: Analysis by Number of Single-use Filtration Systems
5.4. Single-use Centrifugation Systems: List of Products
6. MARKET LANDSCAPE: SINGLE-USE SAMPLING AND CENTRIFUGATION SYSTEMS
6.1. Chapter Overview
6.2. Single-use Sampling Systems: List of Products
6.2.1 Analysis by Type of Sampling Unit
6.2.2. Analysis by Method of Sterilization
6.2.3. Analysis by Key Feature(s)
6.2.4. Analysis by Volume Range (ml)
6.2.5. Analysis by Tubing Material
6.2.5. Analysis by Tubing Material and Volume Range (ml)
6.3. Single-use Sampling Systems: Developer Landscape
6.3.1. Analysis by Year of Establishment
6.3.2. Analysis by Company Size
6.3.3. Analysis by Location of Headquarters
6.3.4. Leading Developers: Analysis by Number of Single-use Sampling Systems
7. MARKET LANDSCAPE: SINGLE-USE CONNECTORS
7.1. Chapter Overview
7.2. Single-use Connectors: List of Products
7.2.1. Analysis by Type of Valve / Gender
7.2.2. Analysis by Pack size (pieces)
7.2.3. Analysis by Operating Temperature
7.2.4. Analysis by Termination Size
7.2.5. Analysis by Material of Construction
7.2.6. Analysis by Application Area
7.3. Single-use Connectors: Developer Landscape
7.3.1. Analysis by Year of Establishment
7.3.2. Analysis by Company Size
7.3.3. Analysis by Location of Headquarters
7.3.4. Leading Developers: Analysis by Number of Single-use Connectors
8. PRODUCT COMPETITIVENESS ANALYSIS
8.1. Chapter Overview
8.2. Methodology
8.3. Assumptions / Key Parameters
8.4. Product Competitiveness Analysis: Single-use Chromatography Systems
8.4.1. Companies Headquartered in North America
8.4.2. Companies Headquartered in Europe
8.5. Product Competitiveness Analysis: Single-use Filtration Systems
8.5.1. Companies Headquartered in North America
8.5.2. Companies Headquartered in Europe and Asia-Pacific
8.6. Product Competitiveness Analysis: Single-use Sampling Systems
8.6.1. Companies Headquartered in North America
8.6.2. Companies Headquartered in Europe
8.6.3. Companies Headquartered in Asia-Pacific and Rest of the World
8.6. Product Competitiveness Analysis: Single-use Connectors
8.6.1. Companies Headquartered in North America
8.6.2. Companies Headquartered in Europe
8.6.3. Companies Headquartered in Asia-Pacific and Rest of the World
9. SINGLE-USE DOWNSTREAM BIOPROCESSING TECHNOLOGY PROVIDERS IN NORTH AMERICA: COMPANY PROFILES
9.1. Chapter Overview
9.2. 3M
9.2.1. Company Overview
9.2.2. Financial Information
9.2.3. Company Offerings
9.2.4. Product Portfolio
9.2.5. Recent Developments and Future Outlook
9.3. Agilitech
9.3.1. Company Overview
9.3.2. Company Offerings
9.3.3. Product Portfolio
9.3.4. Recent Developments and Future Outlook
9.4. CPC (Colder Products Company)
9.4.1. Company Overview
9.4.2. Financial Information
9.4.3. Company Offerings
9.4.4. Product Portfolio
9.4.5. Recent Developments and Future Outlook
9.5. Cytiva Lifesciences
9.5.1. Company Overview
9.5.2. Financial Information
9.5.3. Company Offerings
9.5.4. Product Portfolio
9.5.5. Recent Developments and Future Outlook
9.6. Pall Corporation
9.6.1. Company Overview
9.6.2. Company Offerings
9.6.3. Product Portfolio
9.6.4. Recent Developments and Future Outlook
9.7 Pneumatic Scale Angelus
9.7.1. Company Overview
9.7.2. Company Offerings
9.7.3. Product Portfolio
9.8 Thermo Fisher Scientific
9.8.1. Company Overview
9.8.2. Financial Information
9.8.3. Company Offerings
9.8.4. Product Portfolio
9.8.5. Recent Developments and Future Outlook
10. SINGLE-USE DOWNSTREAM BIOPROCESSING TECHNOLOGY PROVIDERS IN EUROPE AND ASIA-PACIFIC: COMPANY PROFILES
10.1. Chapter Overview
10.2. Keofitt
10.2.1. Company Overview
10.2.2. Financial Information
10.2.3. Company Offerings
10.2.4. Product Portfolio
10.2.5. Recent Developments and Future Outlook
10.3. Merck KGaA
10.3.1. Company Overview
10.3.2. Financial Information
10.3.3. Company Offerings
10.3.4. Product Portfolio
10.3.5. Recent Developments and Future Outlook
10.4. Sartorius
10.4.1. Company Overview
10.4.2. Financial Information
10.4.3. Company Offerings
10.4.4. Product Portfolio
10.4.5. Recent Developments and Future Outlook
10.5. Asahi KASEI
10.5.1. Company Overview
10.5.2. Financial Information
10.5.3. Company Offerings
10.5.4. Product Portfolio
10.5.5. Recent Developments and Future Outlook
10.6. MDI (Advanced Microdevices)
10.6.1. Company Overview
10.6.2. Company Offerings
10.6.3. Product Portfolio
10.6.4. Recent Developments and Future Outlook
11. PATENT ANALYSIS
11.1. Chapter Overview
11.2. Scope and Methodology
11.3. Single-use Downstream Bioprocessing Technology: Patent Analysis
11.3.1. Analysis by Publication Year
11.3.2. Analysis by Application Year
11.3.3. Analysis by Patent Office
11.3.4. Analysis by Geographical Location
11.3.5. Analysis by CPC Symbols
11.3.6. Emerging Focus Area
11.3.7. Analysis by Type of Organization
11.3.8. Leading Players: Analysis by Number of Patents
11.4. Patent Benchmarking Analysis
11.4.1. Analysis by Patent Characteristics
11.5. Analysis by Patent Valuation
12. BRAND POSITIONING MATRIX
12.1. Chapter Overview
12.2 Methodology
12.3. Key Parameters
12.4. Companies Providing Single-use Chromatography Systems
12.4.1. Brand Positioning Matrix: 3M
12.4.2. Brand Positioning Matrix: Sartorius
12.4.3. Brand Positioning Matrix: Agilitech
12.5. Companies Providing Single-use Filtration Systems
12.5.1. Brand Positioning Matrix: Merck KGaA
12.5.2. Brand Positioning Matrix: Sartorius
12.5.3. Brand Positioning Matrix: Thermo Fisher Scientific
12.5.4. Brand Positioning Matrix: Cytiva Lifesciences
12.5.5. Brand Positioning Matrix: Agilitech
12.5.6. Brand Positioning Matrix: Asahi Kasei
12.6. Companies Providing Single-use Sampling Systems
12.6.1. Brand Positioning Matrix: Koefitt
12.6.2. Brand Positioning Matrix: Advanced Microdevices
12.6.3. Brand Positioning Matrix: W. L. Gore & Associates
12.7. Companies Providing Single-use Connectors
12.7.1. Brand Positioning Matrix: CPC (Colder Products Company)
12.7.2. Brand Positioning Matrix: Pall Corporation
12.7.3. Brand Positioning Matrix: Cytiva Lifesciences
12.7.4. Brand Positioning Matrix: Merck KGaA
13. DEMAND AND SUPPLY ANALYSIS
13.1. Chapter Overview
13.2. Key Assumptions and Methodology
13.3. Global Demand for Biologics, 2022-2035
13.3.1. Demand Vs Supply Scenario 1
13.3.2. Demand Vs Supply Scenario 2
13.3.3. Demand Vs Supply Scenario 3
13.4. Concluding Remarks
14. MARKET FORECAST AND OPPORTUNITY ANALYSIS
14.1. Chapter Overview
14.2. Forecast Methodology and Key Assumptions
14.3. Global Single-use Downstream Bioprocessing Technology Market, 2022-2035
14.3.1. Global Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Scale of Operation
14.3.1.1. Global Single-use Downstream Bioprocessing Technology Market for Preclinical / Clinical Operations, 2022-2035
14.3.1.2. Global Single-use Downstream Bioprocessing Technology Market for Commercial Operations, 2022-2035
14.3.2. Global Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Type of Equipment
14.3.2.1. Global Single-use Downstream Bioprocessing Technology Market for Single-Use Chromatography Systems, 2022-2035
14.3.2.2. Global Single-use Downstream Bioprocessing Technology Market for Single-Use Filtration Systems, 2022-2035
14.3.2.3. Global Single-use Downstream Bioprocessing Technology Market for Single-Use Sampling Systems, 2022-2035
14.3.2.4. Global Single-use Downstream Bioprocessing Technology Market for Single-Use Connectors, 2022-2035
14.3.3. Global Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Geographical Region
14.3.3.1. Global Single-use Downstream Bioprocessing Technology Market in North America, 2022-2035
14.3.3.2. Global Single-use Downstream Bioprocessing Technology Market in Europe, 2022-2035
14.3.3.3. Global Single-use Downstream Bioprocessing Technology Market in Asia-Pacific, 2022-2035
14.3.3.4. Global Single-use Downstream Bioprocessing Technology Market in Latin America, 2022-2035
14.3.3.5. Global Single-use Downstream Bioprocessing Technology Market in Middle East and North Africa, 2022-2035
15. CONCLUSION
15.1. Chapter Overview
16. APPENDIX 1: TABULATED DATA
17. APPENDIX 2: LIST OF COMPANIES AND ORGANIZATIONS
LIST OF FIGURES
Figure 4.1. Single-use Chromatography Systems: Distribution by Product / Device Dimensions (cm)
Figure 4.2. Single-use Chromatography Systems: Distribution by Flow Rate (L/min)
Figure 4.3. Single-use Chromatography Systems: Distribution by Volume Range (L)
Figure 4.4. Single-use Chromatography Systems: Distribution by Pressure (Bar)
Figure 4.5. Single-use Chromatography Systems: Distribution by Mode of Operation
Figure 4.6. Single-use Chromatography Systems: Distribution by Weight (Kg)
Figure 4.7. Single-use Chromatography Systems: Distribution by Key Features
Figure 4.8. Single-use Chromatography Systems: Distribution by Scale of Operation
Figure 4.9. Single-use Chromatography Systems: Distribution of Application Area
Figure 4.10. Single-use Chromatography Systems: Distribution of Developers by Year of Establishment
Figure 4.11. Single-use Chromatography Systems: Distribution of Developers by Company Size and Geographical Location
Figure 4.12. Single-use Chromatography Systems: Distribution of Developers by Location of Headquarters
Figure 5.1. Single-use Filtration Systems: Distribution by Filter Pore Size (µm)
Figure 5.2. Single-use Filtration Systems: Distribution by Membrane Construction Material
Figure 5.3. Single-use Filtration Systems: Distribution by Type of Connectors Used
Figure 5.4. Single-use Filtration Systems: Distribution by Maximum Temperature (oC)
Figure 5.5. Single-use Filtration Systems: Distribution by Working Pressure Range (Bar)
Figure 5.6. Single-use Filtration Systems: Distribution by Type of Filters used
Figure 5.7. Single-use Filtration Systems: Distribution by Scale of Operation
Figure 5.8. Single-use Filtration Systems: Distribution by Key Feature(s)
Figure 5.9. Single-use Filtration Systems: Distribution by Application Area
Figure 5.10. Single-use Filtration Systems: Distribution of Developers by Year of Establishment
Figure 5.11. Single-use Filtration Systems: Distribution of Developers by Company Size and Geographical Location
Figure 5.12. Single-use Filtration Systems: Distribution of Developers by Location of Headquarters
Figure 6.1. Single-use Sampling Systems: Distribution by Type of Sampling Unit
Figure 6.2. Single-use Sampling Systems: Distribution by Method of Sterilization
Figure 6.3. Single-use Sampling Systems: Distribution by Key Features(s)
Figure 6.4. Single-use Sampling Systems: Distribution by Volume Range(ml)
Figure 6.5. Single-use Sampling Systems: Distribution by Tubing Material
Figure 6.6. Single-use Sampling Systems: Distribution by Tubing Material and Volume Range
Figure 6.7. Single-use Sampling Systems: Distribution of Developers by Year of Establishment
Figure 6.8. Single-use Sampling Systems: Distribution of Developers by Company Size
Figure 6.9. Single-use Sampling Systems: Distribution of Developers by Location of Headquarters
Figure 7.1. Single-use Connectors: Distribution by Type of Valve / Gender
Figure 7.2. Single-use Connectors: Distribution by Pack Size (pieces)
Figure 7.3. Single-use Connectors: Distribution by Operating Temperature (oC)
Figure 7.4. Single-use Connectors: Distribution by Termination Size
Figure 7.5. Single-use Connectors: Distribution by Material of Construction
Figure 7.6. Single-use Connectors: Distribution by Application Area
Figure 7.7. Single-use Connectors: Distribution of Developers by Year of Establishment
Figure 7.8. Single-use Connectors: Distribution of Developers by Company Size
Figure 7.9. Single-use Connectors: Distribution of Developers by Location of Headquarters
Figure 8.1. Product Competitiveness Analysis: Single-use Chromatography System developers based in North America
Figure 8.2. Product Competitiveness Analysis: Single-use Chromatography System developers based in Europe
Figure 8.3. Product Competitiveness Analysis: Single-use Filter developers based in North America
Figure 8.4. Product Competitiveness Analysis: Single-use Filter developers based in Europe and Asia Pacific
Figure 8.5. Product Competitiveness Analysis: Single-use Sampling System developers based in North America, Europe and Asia Pacific
Figure 8.6. Product Competitiveness Analysis: Single-use Connector developers based in North America
Figure 8.7. Product Competitiveness Analysis: Single-use Connector developers based in Europe
Figure 9.1. 3M: Annual Revenues, 2017- 2021 (USD Billion)
Figure 9.2. CPC: Annual Revenues, 2017- 2021 (USD Million)
Figure 9.3. Cytiva: Annual Revenues, 2016 – 9M 2021 (USD Billion)
Figure 9.4. Thermo Fisher Scientific: Annual Revenues, 2017- 2021 (USD Million)
Figure 10.1. Merck KGaA: Annual Revenues, 2017- 9M 2021 (EUR Million)
Figure 10.2. Sartorius: Annual Revenues, 2017- 9M 2021 (EUR Million)
Figure 10.3. Asahi Kasei: Annual Revenues, 2017- Q2 2021 (YEN Billion)
Figure 11.1. Patent Analysis: Cumulative Distribution by Publication Year
Figure 11.2. Patent Analysis: Distribution by Type of Patents
Figure 11.3. Patent Analysis: Distribution by Publication Year
Figure 11.4. Patent Analysis: Distribution by Geographical Region
Figure 11.5. Patent Analysis: Distribution by Issuing Authority
Figure 11.6. Patent Analysis: Distribution by Granted Patents and Patent Application
Figure 11.7. Patent Analysis: Distribution by Publication Year
Figure 11.8. Patent Analysis: Cumulative Distribution by Organization Type
Figure 11.9. Patent Analysis: Distribution by Patent Age
Figure 11.10. Patent Analysis: Distribution by Leading Industry Players
Figure 11.11. Patent Analysis: Distribution by Leading Academic Players
Figure 11.12. Patent Analysis: Distribution by Leading Investors
Figure 11.13. Patent Analysis: Distribution by CPC Symbols
Figure 11.14. Patent Analysis: Patent Valuation Analysis
Figure 12.1. Brand Positioning Matrix of Single-use Chromatography Systems: 3M
Figure 12.2. Brand Positioning Matrix of Single-use Chromatography Systems: Agilitech
Figure 12.3. Brand Positioning Matrix of Single-use Chromatography Systems: Sartorius
Figure 12.4. Brand Positioning Matrix of Single-use Filters: Agilitech
Figure 12.5. Brand Positioning Matrix of Single-use Filters: Asahi Kasei
Figure 12.6. Brand Positioning Matrix of Single-use Filters: Cytiva
Figure 12.7. Brand Positioning Matrix of Single-use Filters: Merck KGaA
Figure 12.8. Brand Positioning Matrix of Single-use Filters: Sartorius
Figure 12.9. Brand Positioning Matrix of Single-use Filters: Thermo Fisher Scientific
Figure 12.10. Brand Positioning Matrix of Single-use Sampling Systems: Advanced Microdevices
Figure 12.11. Brand Positioning Matrix of Single-use Sampling Systems: Koefitt
Figure 12.12. Brand Positioning Matrix of Single-use Sampling Systems: W. L. Gore & Associates
Figure 12.13. Brand Positioning Matrix of Connectors: CPC
Figure 12.14. Brand Positioning Matrix of Connectors: Cytiva
Figure 12.15. Brand Positioning Matrix of Connectors: Merck KGaA
Figure 12.16. Brand Positioning Matrix of Connectors: Pall Corporation
Figure 13.1. Demand and Supply Analysis: Demand for Biologics, 2022-2035
Figure 13.2. Demand and Supply: Analysis by Likely Scenarios, 2022-2035
Figure 14.1. Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Scale of Operation (USD million)
Figure 14.2. Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Type of Equipment (USD million)
Figure 14.3. Single-use Downstream Bioprocessing Technology Market for Single-use Chromatography Systems, 2022-2035 (USD million)
Figure 14.4. Single-use Downstream Bioprocessing Technology Market for Single-use Filtration Systems, 2022-2035 (USD million)
Figure 14.5. Single-use Downstream Bioprocessing Technology Market for Single-use Centrifugation Systems, 2022-2035 (USD million)
Figure 14.6. Single-use Downstream Bioprocessing Technology Market for Single-use Connectors, 2022-2035 (USD million)
Figure 14.7. Single-use Downstream Bioprocessing Technology Market, 2022-2035: Distribution by Geography (USD million)
Figure 14.8. Single-use Downstream Bioprocessing Technology Market in North America, 2022-2035 (USD million)
Figure 14.9. Single-use Downstream Bioprocessing Technology Market in North America, 2022-2035: Distribution by Type of Equipment (USD million)
Figure 14.10. Single-use Downstream Bioprocessing Technology Market in Europe, 2022-2035 (USD million)
Figure 14.11. Single-use Downstream Bioprocessing Technology Market in Europe, 2022-2035: Distribution by Type of Equipment (USD million)
Figure 14.12. Single-use Downstream Bioprocessing Technology Market in Asia-Pacific, 2022-2035 (USD million)
Figure 14.13. Single-use Downstream Bioprocessing Technology Market, 2022-2035 in Asia-Pacific: Distribution by Type of Equipment (USD million)
Figure 14.14. Single-use Downstream Bioprocessing Technology Market in Latin America, 2022-2035 (USD million)
Figure 14.15. Single-use Downstream Bioprocessing Technology Market in Latin America, 2022-2035: Distribution by Type of Equipment (USD million)
Figure 14.16. Single-use Downstream Bioprocessing Technology Market in Middle East and North Africa, 2022-2035 (USD million)
Figure 14.17. Single-use Downstream Bioprocessing Technology Market in Middle East and North Africa, 2022-2035: Distribution by Type of Equipment (USD million)
LIST OF TABLES
Table 4.1. Single-use Chromatography Systems: Information on Developers, Product / Device Specifications, Product / Device Key Features, Scale of Operation and Application Areas
Table 5.1. Single-use Filtration Systems: Information on Developers, Product / Device Specifications, Product / Device Key Features, Scale of Operation and Application Areas
Table 6.1. Single-use Sampling Systems: Information on Developers, Material of Construction, Sampling Unit, Method of Sterilization, Key Features and Application Areas
Table 6.2. Single-use Centrifugation Systems: Information on Developers, Product / Device Specifications, Product / Device Key Features, Scale of Operation and Application Areas
Table 7.1. Single-use Connectors: Information on Developers, Material of Construction, Gender/ Valve, Method of Sterilization and Application Areas
Table 9.1. Avantor: Product Portfolio
Table 9.2. 3M: Product Portfolio
Table 9.3. Agilitech: Product Portfolio
Table 9.4. CPC: Product Portfolio
Table 9.5. Cytiva: Product Portfolio
Table 9.6. Pall Corporation: Product Portfolio
Table 9.7. Pneumatic Scale Angelus: Product Portfolio
Table 9.8. Thermo Fisher Scientific: Product Portfolio
Table 9.9. Keofitt: Product Portfolio
Table 9.10. Merck KGaA: Product Portfolio
Table 9.11. Sartorius: Product Portfolio
Table 10.1. Asahi KASEI: Product Portfolio
Table 10.2. MDI (Advanced Microdevices): Product Portfolio
Table 11.1. Patent Analysis: List of Filed / Granted Patents
LIST OF COMPANIES AND ORGANIZATIONS
1. 3M
2. Automated Engineering Services (AES)
3. Agilitech
4. Alfa Laval
5. ARTeSYN Biosolutions (a subsidiary of Repligen)
6. Asahi Kasei Medical
7. Avantor
8. Colder Products Company (CPC)
9. Cytiva
10. Danaher
11. DrM
12. ESI Ultrapure
13. GEA
14. Keofitt
15. Liquidyne
16. MDI
17. Merck KGaA
18. Pall Corporation
19. Parker Bioscience
20. Pneumatic Scale Angelus (PSA)
21. Refine Technology
22. Repligen
23. Saint-Gobain
24. Sartorius
25. Sepragen
26. Thermo Fisher Scientific
27. Tosoh Corporation
28. W. L. Gore & Associates
29. WaterSep BioSeparations (acquired by Sartorius)

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