Single Use Sensors Market for Bioprocessing by Type of Sensor, Type of Bioprocessing and Key Geographical Regions (North America, Europe, Asia Pacific and Rest of the World): Industry Trends and Global Forecasts, 2021-2035
Single Use Sensors Market by Type of Sensor (Conductivity, Flow, pH, Pressure and Temperature), Type of Bioprocessing (Upstream, Downstream and Both), and Key Geographical Regions (North America, Europe, Asia Pacific and Rest of the World): Industry Trends and Global Forecasts, 2021-2035
Report Link: https://www.rootsanalysis.com/reports/single-use-sensors-for-bioprocessing.html
The market for single-use sensors in bioprocessing is currently estimated at $280 million in 2022 and is projected to experience a robust compound annual growth rate (CAGR) of 15% over the forecast period.
With several blockbuster drugs already on the market and many more in the development pipeline, the modern biopharmaceutical industry is poised for significant growth in the coming years. The success of biopharmaceutical drugs has necessitated an upgrade in conventional biologics manufacturing equipment. Consequently, the industry has witnessed various technological advancements, including the adoption of controllers and automated systems.
Sensors and controllers are pivotal components of bioprocess control systems, ensuring that processes remain within precise parameters by making necessary adjustments. Sensors collect data and transmit it to the controller, which then instructs valves to maintain the desired environmental conditions throughout the manufacturing process. This not only minimizes the risk of human errors but also enhances product quality. Over time, single-use sensors have gained popularity due to their advantages, such as a lower risk of contamination, ease of use, and accuracy and robustness comparable to conventional measurement techniques.
A significant portion of single-use bioreactors is now equipped with single-use sensors to measure various variables, including conductivity, dissolved oxygen, pH, and pressure. Moreover, several developers offer customized single-use sensors tailored to meet the specific requirements of research and manufacturing protocols. Some single-use sensors are pre-installed or integrated into other single-use systems, such as bioreactors, bags, and fermenters. It's worth noting that the ongoing COVID-19 pandemic has led to an increased demand for advanced biomanufacturing solutions, with single-use systems being extensively utilized in the production of various COVID-19 vaccines. This situation presents lucrative opportunities for companies operating in the single-use sensors market. Driven by the growing adoption of single-use systems and technologies, the single-use sensors market is expected to witness substantial growth throughout the forecast period.
Key Market Segments
Type of Sensor
Report Link: https://www.rootsanalysis.com/reports/single-use-sensors-for-bioprocessing.html
The market for single-use sensors in bioprocessing is currently estimated at $280 million in 2022 and is projected to experience a robust compound annual growth rate (CAGR) of 15% over the forecast period.
With several blockbuster drugs already on the market and many more in the development pipeline, the modern biopharmaceutical industry is poised for significant growth in the coming years. The success of biopharmaceutical drugs has necessitated an upgrade in conventional biologics manufacturing equipment. Consequently, the industry has witnessed various technological advancements, including the adoption of controllers and automated systems.
Sensors and controllers are pivotal components of bioprocess control systems, ensuring that processes remain within precise parameters by making necessary adjustments. Sensors collect data and transmit it to the controller, which then instructs valves to maintain the desired environmental conditions throughout the manufacturing process. This not only minimizes the risk of human errors but also enhances product quality. Over time, single-use sensors have gained popularity due to their advantages, such as a lower risk of contamination, ease of use, and accuracy and robustness comparable to conventional measurement techniques.
A significant portion of single-use bioreactors is now equipped with single-use sensors to measure various variables, including conductivity, dissolved oxygen, pH, and pressure. Moreover, several developers offer customized single-use sensors tailored to meet the specific requirements of research and manufacturing protocols. Some single-use sensors are pre-installed or integrated into other single-use systems, such as bioreactors, bags, and fermenters. It's worth noting that the ongoing COVID-19 pandemic has led to an increased demand for advanced biomanufacturing solutions, with single-use systems being extensively utilized in the production of various COVID-19 vaccines. This situation presents lucrative opportunities for companies operating in the single-use sensors market. Driven by the growing adoption of single-use systems and technologies, the single-use sensors market is expected to witness substantial growth throughout the forecast period.
Key Market Segments
Type of Sensor
- Conductivity
- Flow
- Ph
- Pressure
- Temperature
- Upstream
- Downstream
- Both
- North America
- Europe
- Asia Pacific
- Rest of the World
- The report studies the single use sensors market by type of sensor, type of bioprocessing and key geographical regions.
- The report analyzes factors (such as drivers, restraints, opportunities, and challenges) affecting the market growth.
- The report assesses the potential advantages and obstacles within the market for those involved and offers information on the competitive environment for top players in the market.
- The report forecasts the revenue of market segments with respect to major regions.
- An overview of key findings from our research on the single use sensors market, offering insights into its current state and likely evolution in the short, mid, and long term.
- A comprehensive evaluation of the overall market landscape of single-use sensors, considering various relevant parameters, such as sensor type (conductivity, flow, pH probe, pressure, and temperature), bioprocessing type, measurement range, operating temperature, sterilization technique, material composition, and application area. Furthermore, the chapter offers insights into companies participating in single-use sensor development, providing details like their founding year, company size, and headquarters location.
- A detailed analysis of the competitive landscape among different types of single-use sensors, taking into account several pertinent parameters, such as product applicability (based on controlled processes and applications) and product strengths (based on essential features and sterilization techniques employed).
- In-depth profiles of leading players involved in single-use sensor development. Each company profile includes a concise overview of the company, information regarding its product portfolio, recent advancements, and an informed outlook for the future.
- A contemporary case study on pre-installed single-use sensor systems, subject to analysis based on multiple parameters, including sensor type, measuring range, operating temperature, and applications. Additionally, it provides insights into the developer landscape, encompassing data on their establishment year, company size, and headquarters location.
- An insightful case study on the market landscape of single-use bioreactors, considering a range of parameters such as development status (commercially available or under development), bioreactor type (stirred tank, pneumatically mixed, rocker/rotating, wave-induced, paddle sleeve, fixed-bed, hollow fiber, diffusion, orbitally shaken, and others), operational scale (laboratory, pilot, and large scale), application areas (cancer research, drug discovery/toxicology testing, stem cell research, tissue engineering/regenerative medicine, and others), working volume, bioreactor weight, stirrer speed, handled cell cultures (mammalian, insect, microbial, viral, plant, bacterial, and others), and type of molecules (vaccine, monoclonal antibody, recombinant protein, stem cell, cell therapy, gene therapy, and others). The case study includes a contemporary market trend analysis that comprises [A] a treemap comparing bioreactor types and company sizes, [B] a grid representation based on operational scale, application area, and cell culture type, [C] a heatmap analyzing bioreactor types and application areas, and [D] a world map representing the regional distribution of players based on their headquarters location. Additionally, it provides information about companies engaged in single-use bioreactor development, including their founding year, company size, and headquarters location.
- A detailed case study on the market landscape of various types of bioprocess controllers, considering important parameters like operational scale (laboratory, clinical, and commercial), key features (scalability/ease of use, visual data display, remote accessibility, built-in system control sensors, extensive I/O compatibility, and provisions for alarms/alerts), compatibility with bioreactor systems (stirred tank (glass), single-use bioreactor, stirred tank (steel), fermenter, rocking motion), mode of operation (batch, fed-batch, and perfusion), and the types of processes controlled (cell cultivation and microbial fermentation). Additionally, the chapter provides insights into companies involved in bioprocess controller development, including information on their establishment year, company size, and headquarters location.
- The report offers market leaders and newcomers valuable insights into revenue estimations for both the overall market and its sub-segments.
- Stakeholders can utilize the report to enhance their understanding of the competitive landscape, allowing for improved business positioning and more effective go-to-market strategies.
- The report provides stakeholders with a pulse on the single use sensors market, furnishing them with essential information on significant market drivers, barriers, opportunities, and challenges.
- You will get access to complimentary PPT insights and excel data packs / dynamic dashboards to easily navigate through complex analyses / charts.
- Applied Biosensors
- Levitronix
- Malema Engineering
- Masterflex (acquired by Avantor)
- Parker Hannifin
- PendoTECH (acquired by METTLER TOLEDO)
- PreSens Precision Sensing and Finesse Solutions (acquired by Thermo Fisher Scientific)
1. PREFACE
1.1. Scope of the Report
1.2. Research Methodology
1.3. Key Questions Answered
1.4. Chapter Outlines
2. EXECUTIVE SUMMARY
3. INTRODUCTION
3.1. Chapter Overview
3.2. Bioprocess Control
3.3. Process Control Systems
3.3.1. Components of Process Control Systems
3.3.1.1. Actuators
3.3.3.2. Controllers
3.3.3.3 Sensors
3.4. Single-use Sensors
3.4.1. Types of Single-use Sensors
3.5. Single-use Technology in Bioprocessing
3.5.1. Applications of Single-use Technologies
3.5.2. Advantages of Single-use Technologies
3.5.3. Challenges Associated with Single-use Technologies
3.6. Future Perspectives
4. MARKET OVERVIEW
4.1. Chapter Overview
4.2. Single-use Sensors for Bioprocessing: List of Products
4.2.1 Analysis by Type of Sensor
4.2.2. Analysis by Type of Bioprocessing
4.2.3. Analysis by Operating Temperature
4.3. Single-use Sensors for Bioprocessing: Information on Sterilization Technique
4.3.1. Analysis by Sterilization Technique
4.4. Single-use Sensors for Bioprocessing: List of Additional Parameters of Products
4.4.1. Analysis by Sensor Calibration
4.4.2. Analysis by Type of Material Used
4.4.3. Analysis by Application Area
4.4. Single-use Sensors for Bioprocessing: Developer Landscape
4.4.1. Analysis by Year of Establishment
4.4.2. Analysis by Company Size
4.4.3. Analysis by Location of Headquarters
5. PRODUCT COMPETITIVENESS ANALYSIS
5.1. Chapter Overview
5.2. Methodology
5.3. Assumptions / Key Parameters
5.4. Product Competitiveness Analysis: Flow Sensors
5.5. Product Competitiveness Analysis: Pressure Sensors
5.6. Product Competitiveness Analysis: pH Sensors
5.7. Product Competitiveness Analysis: Conductivity and Temperature Sensors
6. COMPANY PROFILES
6.1. Chapter Overview
6.2. Applied Biosensors
6.2.1. Company Overview
6.2.2. Single-use Sensor Product Portfolio
6.2.3. Recent Developments and Future Outlook
6.3. Levitronix
6.3.1. Company Overview
6.3.2. Single-use Sensor Product Portfolio
6.3.3. Recent Developments and Future Outlook
6.4. Malema Engineering
6.4.1. Company Overview
6.4.2. Single-use Sensor Product Portfolio
6.4.3. Recent Developments and Future Outlook
6.5. Masterflex (acquired by Avantor)
6.5.1. Company Overview
6.5.2. Single-use Sensor Product Portfolio
6.5.3. Recent Developments and Future Outlook
6.6. Parker Hannifin
6.6.1. Company Overview
6.6.2. Single-use Sensor Product Portfolio
6.6.3. Recent Developments and Future Outlook
6.7. PendoTECH (acquired by METTLER TOLEDO)
6.7.1. Company Overview
6.7.2. Single-use Sensor Product Portfolio
6.7.3. Recent Developments and Future Outlook
6.8. PreSens Precision Sensing
6.8.1. Company Overview
6.8.2. Single-use Sensor Product Portfolio
6.8.3. Recent Developments and Future Outlook
6.9. Finesse Solutions (acquired by Thermo Fisher Scientific)
6.9.1. Company Overview
6.9.2. Single-use Sensor Product Portfolio
6.9.3. Recent Developments and Future Outlook
7. CASE STUDY: PRE-INSTALLED SINGLE-USE SENSOR SYSTEMS
7.1. Chapter Overview
7.2. Pre-installed Single-use Sensors for Bioprocessing: List of Products
7.2.1 Analysis by Type of Sensor
7.2.2. Analysis by Operating Temperature
7.2.3. Analysis by Sensor Calibration
7.2.4. Analysis by Application Area
7.3. Pre-installed Single-use Sensors for Bioprocessing: 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
8. CASE STUDY: SINGLE-USE BIOREACTORS
8.1. Chapter Overview
8.2. Single-use Bioreactors: Overall Market Landscape
8.2.1. Analysis by Status of Development
8.2.2. Analysis by Type of Single-use Bioreactor
8.2.3. Analysis by Scale of Operation
8.2.4. Analysis by Area of Application
8.2.5. Analysis by Working Volume
8.2.6. Analysis by Weight of Bioreactor
8.2.7. Analysis by Stirrer Speed
8.2.8. Analysis by Type of Cell Culture Handled
8.2.9. Analysis by Type of Molecule
8.3. Single-use Bioreactor Manufacturers: Overall Market Landscape
8.3.1. Analysis by Year of Establishment
8.3.2. Analysis by Company Size
8.3.3. Analysis by Location of Headquarters
8.3.4. Leading Manufacturers: Analysis by Number of Products8.4. Tree Map Representation: Analysis by Type of Single-use Bioreactor and Company Size
8.5. Heat Map Representation: Analysis by Scale of Operation, Area of Application and Type of Cell Culture Handled
8.6. Heat Map Representation: Analysis by Type of Single-use Bioreactor and Area of Application
8.7. World Map Representation: Analysis by Location of Headquarters
9. CASE STUDY: BIOPROCESS CONTROLLERS
9.1. Chapter Overview
9.2. Bioprocess Control Software: Overall Market Landscape
9.2.1. Analysis by Scale of Operation
9.2.2. Analysis by Key Features
9.2.3. Analysis by Compatibility with Systems
9.2.4. Analysis by Types of Processes Controlled
9.3. Bioprocess Control Software Developers: Overall Market Landscape
9.3.1. Analysis by Year of Establishment
9.3.2. Analysis by Company Size
9.3.3. Analysis by Location of Headquarters
9.4. Upstream Controllers: Overall Market Landscape
9.4.1. Analysis by Scale of Operation
9.4.2. Analysis by Key Features
9.4.3. Analysis by Compatibility with Bioreactor System
9.4.4. Analysis by Operation Mode
9.4.5. Analysis by Types of Processes Controlled
9.5. Upstream Controller Developers: Overall Market Landscape
9.5.1. Analysis by Year of Establishment
9.5.2. Analysis by Company Size
9.5.3. Analysis by Location of Headquarters
9.6. Downstream Controller Systems: Overall Market Landscape
9.6.1. Analysis by Scale of Operation
9.6.2. Analysis by Key Features
9.6.3. Analysis by Types of Systems
9.6.4. Analysis by Operation Mode
9.6.5. Analysis by Application Area
9.7. Downstream Controller System Developers: Overall Market Landscape
9.7.1. Analysis by Year of Establishment
9.7.2. Analysis by Company Size
9.7.3. Analysis by Location of Headquarters
10. MARKET FORECAST AND OPPORTUNITY ANALYSIS
10.1. Chapter Overview
10.2. Forecast Methodology and Key Assumptions
10.3. Global Single-use Sensors for Bioprocessing Market, 2021-2035
10.4. Global Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Sensor
10.4.1. Single-use Sensors for Bioprocessing Market for Conductivity Sensors, 2021-2035
10.4.2. Single-use Sensors for Bioprocessing Market for Dissolved Oxygen Sensors, 2021-2035
10.4.3. Single-use Sensors for Bioprocessing Market for Flow Sensors, 2021-2035
10.4.4. Single-use Sensors for Bioprocessing Market for pH Sensors, 2021-2035
10.4.5. Single-use Sensors for Bioprocessing Market for Pressure Sensors, 2021-2035
10.4.6. Single-use Sensors for Bioprocessing Market for Temperature Sensors, 2021-2035
10.5. Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Bioprocessing
10.5.1. Single-use Sensors for Bioprocessing Market for Upstream Bioprocessing, 2021-2035
10.5.2. Single-use Sensors for Bioprocessing Market for Downstream Bioprocessing, 2021-2035
10.6. Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Key Geographical Regions
10.6.1. Single-use Sensors for Bioprocessing Market in North America, 2021-2035
10.6.2. Single-use Sensors for Bioprocessing Market in Europe, 2021-2035
10.6.3. Single-use Sensors for Bioprocessing Market in Asia Pacific and Rest of the World, 2021-2035
11. CONCLUDING REMARKS
11.1. Chapter Overview
12. APPENDIX 1: TABULATED DATA
13. APPENDIX 2: LIST OF COMPANIES AND ORGANIZATIONS
1.1. Scope of the Report
1.2. Research Methodology
1.3. Key Questions Answered
1.4. Chapter Outlines
2. EXECUTIVE SUMMARY
3. INTRODUCTION
3.1. Chapter Overview
3.2. Bioprocess Control
3.3. Process Control Systems
3.3.1. Components of Process Control Systems
3.3.1.1. Actuators
3.3.3.2. Controllers
3.3.3.3 Sensors
3.4. Single-use Sensors
3.4.1. Types of Single-use Sensors
3.5. Single-use Technology in Bioprocessing
3.5.1. Applications of Single-use Technologies
3.5.2. Advantages of Single-use Technologies
3.5.3. Challenges Associated with Single-use Technologies
3.6. Future Perspectives
4. MARKET OVERVIEW
4.1. Chapter Overview
4.2. Single-use Sensors for Bioprocessing: List of Products
4.2.1 Analysis by Type of Sensor
4.2.2. Analysis by Type of Bioprocessing
4.2.3. Analysis by Operating Temperature
4.3. Single-use Sensors for Bioprocessing: Information on Sterilization Technique
4.3.1. Analysis by Sterilization Technique
4.4. Single-use Sensors for Bioprocessing: List of Additional Parameters of Products
4.4.1. Analysis by Sensor Calibration
4.4.2. Analysis by Type of Material Used
4.4.3. Analysis by Application Area
4.4. Single-use Sensors for Bioprocessing: Developer Landscape
4.4.1. Analysis by Year of Establishment
4.4.2. Analysis by Company Size
4.4.3. Analysis by Location of Headquarters
5. PRODUCT COMPETITIVENESS ANALYSIS
5.1. Chapter Overview
5.2. Methodology
5.3. Assumptions / Key Parameters
5.4. Product Competitiveness Analysis: Flow Sensors
5.5. Product Competitiveness Analysis: Pressure Sensors
5.6. Product Competitiveness Analysis: pH Sensors
5.7. Product Competitiveness Analysis: Conductivity and Temperature Sensors
6. COMPANY PROFILES
6.1. Chapter Overview
6.2. Applied Biosensors
6.2.1. Company Overview
6.2.2. Single-use Sensor Product Portfolio
6.2.3. Recent Developments and Future Outlook
6.3. Levitronix
6.3.1. Company Overview
6.3.2. Single-use Sensor Product Portfolio
6.3.3. Recent Developments and Future Outlook
6.4. Malema Engineering
6.4.1. Company Overview
6.4.2. Single-use Sensor Product Portfolio
6.4.3. Recent Developments and Future Outlook
6.5. Masterflex (acquired by Avantor)
6.5.1. Company Overview
6.5.2. Single-use Sensor Product Portfolio
6.5.3. Recent Developments and Future Outlook
6.6. Parker Hannifin
6.6.1. Company Overview
6.6.2. Single-use Sensor Product Portfolio
6.6.3. Recent Developments and Future Outlook
6.7. PendoTECH (acquired by METTLER TOLEDO)
6.7.1. Company Overview
6.7.2. Single-use Sensor Product Portfolio
6.7.3. Recent Developments and Future Outlook
6.8. PreSens Precision Sensing
6.8.1. Company Overview
6.8.2. Single-use Sensor Product Portfolio
6.8.3. Recent Developments and Future Outlook
6.9. Finesse Solutions (acquired by Thermo Fisher Scientific)
6.9.1. Company Overview
6.9.2. Single-use Sensor Product Portfolio
6.9.3. Recent Developments and Future Outlook
7. CASE STUDY: PRE-INSTALLED SINGLE-USE SENSOR SYSTEMS
7.1. Chapter Overview
7.2. Pre-installed Single-use Sensors for Bioprocessing: List of Products
7.2.1 Analysis by Type of Sensor
7.2.2. Analysis by Operating Temperature
7.2.3. Analysis by Sensor Calibration
7.2.4. Analysis by Application Area
7.3. Pre-installed Single-use Sensors for Bioprocessing: 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
8. CASE STUDY: SINGLE-USE BIOREACTORS
8.1. Chapter Overview
8.2. Single-use Bioreactors: Overall Market Landscape
8.2.1. Analysis by Status of Development
8.2.2. Analysis by Type of Single-use Bioreactor
8.2.3. Analysis by Scale of Operation
8.2.4. Analysis by Area of Application
8.2.5. Analysis by Working Volume
8.2.6. Analysis by Weight of Bioreactor
8.2.7. Analysis by Stirrer Speed
8.2.8. Analysis by Type of Cell Culture Handled
8.2.9. Analysis by Type of Molecule
8.3. Single-use Bioreactor Manufacturers: Overall Market Landscape
8.3.1. Analysis by Year of Establishment
8.3.2. Analysis by Company Size
8.3.3. Analysis by Location of Headquarters
8.3.4. Leading Manufacturers: Analysis by Number of Products8.4. Tree Map Representation: Analysis by Type of Single-use Bioreactor and Company Size
8.5. Heat Map Representation: Analysis by Scale of Operation, Area of Application and Type of Cell Culture Handled
8.6. Heat Map Representation: Analysis by Type of Single-use Bioreactor and Area of Application
8.7. World Map Representation: Analysis by Location of Headquarters
9. CASE STUDY: BIOPROCESS CONTROLLERS
9.1. Chapter Overview
9.2. Bioprocess Control Software: Overall Market Landscape
9.2.1. Analysis by Scale of Operation
9.2.2. Analysis by Key Features
9.2.3. Analysis by Compatibility with Systems
9.2.4. Analysis by Types of Processes Controlled
9.3. Bioprocess Control Software Developers: Overall Market Landscape
9.3.1. Analysis by Year of Establishment
9.3.2. Analysis by Company Size
9.3.3. Analysis by Location of Headquarters
9.4. Upstream Controllers: Overall Market Landscape
9.4.1. Analysis by Scale of Operation
9.4.2. Analysis by Key Features
9.4.3. Analysis by Compatibility with Bioreactor System
9.4.4. Analysis by Operation Mode
9.4.5. Analysis by Types of Processes Controlled
9.5. Upstream Controller Developers: Overall Market Landscape
9.5.1. Analysis by Year of Establishment
9.5.2. Analysis by Company Size
9.5.3. Analysis by Location of Headquarters
9.6. Downstream Controller Systems: Overall Market Landscape
9.6.1. Analysis by Scale of Operation
9.6.2. Analysis by Key Features
9.6.3. Analysis by Types of Systems
9.6.4. Analysis by Operation Mode
9.6.5. Analysis by Application Area
9.7. Downstream Controller System Developers: Overall Market Landscape
9.7.1. Analysis by Year of Establishment
9.7.2. Analysis by Company Size
9.7.3. Analysis by Location of Headquarters
10. MARKET FORECAST AND OPPORTUNITY ANALYSIS
10.1. Chapter Overview
10.2. Forecast Methodology and Key Assumptions
10.3. Global Single-use Sensors for Bioprocessing Market, 2021-2035
10.4. Global Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Sensor
10.4.1. Single-use Sensors for Bioprocessing Market for Conductivity Sensors, 2021-2035
10.4.2. Single-use Sensors for Bioprocessing Market for Dissolved Oxygen Sensors, 2021-2035
10.4.3. Single-use Sensors for Bioprocessing Market for Flow Sensors, 2021-2035
10.4.4. Single-use Sensors for Bioprocessing Market for pH Sensors, 2021-2035
10.4.5. Single-use Sensors for Bioprocessing Market for Pressure Sensors, 2021-2035
10.4.6. Single-use Sensors for Bioprocessing Market for Temperature Sensors, 2021-2035
10.5. Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Bioprocessing
10.5.1. Single-use Sensors for Bioprocessing Market for Upstream Bioprocessing, 2021-2035
10.5.2. Single-use Sensors for Bioprocessing Market for Downstream Bioprocessing, 2021-2035
10.6. Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Key Geographical Regions
10.6.1. Single-use Sensors for Bioprocessing Market in North America, 2021-2035
10.6.2. Single-use Sensors for Bioprocessing Market in Europe, 2021-2035
10.6.3. Single-use Sensors for Bioprocessing Market in Asia Pacific and Rest of the World, 2021-2035
11. CONCLUDING REMARKS
11.1. Chapter Overview
12. APPENDIX 1: TABULATED DATA
13. APPENDIX 2: LIST OF COMPANIES AND ORGANIZATIONS
