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1063758

Single-use Sensors for Bioprocessing Market by Type of Sensor (conductivity, flow, pH, pressure and temperature), Type of Bioprocessing (upstream, downstream and both), and Key Geographical Regions

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Single-use Sensors for Bioprocessing Market by Type of Sensor (conductivity, flow, pH, pressure and temperature), Type of Bioprocessing (upstream, downstream and both), and Key Geographical Regions
Published: January 31, 2022
Roots Analysis
Content info: 210 Pages
Delivery time: 1-2 business days
  • Description
  • Table of Contents
  • List of Tables

Title:
Single-use Sensors for Bioprocessing
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.

Example Insights:

Overview

With several blockbuster drugs in the market and numerous others in the development pipeline, the modern biopharmaceutical industry is poised to grow at a significant pace over the coming years. The success of biopharmaceutical drugs has necessitated an upgrade of conventional biologics manufacturing equipment. As a result, the domain has witnessed several technological advancements, including the adoption of controllers and automated systems. Sensors and controllers are the essential elements of the bioprocess control system, which ensure that the processes continue to run within precise limits by making the necessary adjustments. Sensors transmit the information to the controller, which further instructs the valves to maintain the desirable environmental conditions in the overall manufacturing process. This helps in minimizing the risk of human errors and improving the product quality. Over time, single-use sensors have gained popularity; these sensors offer various benefits, such as low risk of contamination, ease of use, while providing the accuracy and robustness similar to the conventional measurement techniques.

A relatively larger proportion of the bioreactors are now equipped with single-use sensors, which measure variables such as conductivity, dissolved oxygen, pH and pressure. In fact, several developers are also providing customized single-use sensors as per the standard requirements of the research / manufacturing protocol. In addition, there are some single-use sensors that are pre-installed / integrated in other single-use systems such as single-use bioreactors, bags and fermenters. It is worth highlighting that the ongoing COVID-19 pandemic has led to an increased demand for such advanced biomanufacturing solutions, as single-use systems are extensively being used in the production of various COVID-19 vaccines. This presents lucrative opportunities for companies engaged in this domain. Driven by the increasing adoption of single-use systems / technologies, the single-use sensors market is anticipated to witness substantial growth over the next decade.

Scope of the Report

The "Single-use Sensors for Bioprocessing 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 features an extensive study of the current market landscape and the likely evolution of single-use sensors market in the mid to long-term. The study underlines an in-depth analysis, highlighting the capabilities of various industry stakeholders engaged in this field. In addition to other elements, the report includes:

  • A detailed assessment of the overall market landscape of single-use sensors, based on several relevant parameters, such as type of sensor (conductivity, flow, pH, pressure and temperature) , type of bioprocessing, measurement range, operating temperature, sterilization technique, material used and application area. In addition, the chapter presents details of the companies involved in the development of single-use sensors, including information on their year of establishment, company size, and location of headquarters.
  • A detailed competitiveness analysis of various types of single-use sensors, taking into consideration several relevant parameters, such as the product applicability (based on the type of processes controlled and applications) and product strength (based on the key features and sterilization technique used) .
  • Elaborate profiles of prominent players engaged in the development of single-use sensors. Each company profile features a brief overview of the company, information on its product portfolio, recent developments and an informed future outlook.
  • A contemporary case study on pre-installed single-use sensor systems and their analyses based on multiple parameters, including type of sensor, measuring range, operating temperature and applications. In addition, it provides details on developer landscape, including information on their year of establishment, company size, and location of headquarters.
  • An insightful case study on the market landscape of single-use bioreactors, based on a number of parameters, such as status of development (commercially available / under development), type of single-use bioreactor (stirred tank, pneumatically mixed, rocker / rotating, wave-induced, paddle sleeve, fixed-bed, hollow fiber, diffusion, orbitally shaken, and others), scale of operation (laboratory scale, pilot scale, and large scale), area of application (cancer research, drug discovery / toxicology testing, stem cell research, tissue engineering / regenerative medicine, and others), working volume, weight of bioreactor, stirrer speed, cell culture handled (mammalian, insect, microbial, viral, plant, bacterial, and others), and type of molecule (vaccine, monoclonal antibody, recombinant protein, stem cell, cell therapy, gene therapy, and others). A contemporary market trend analysis, which includes [A] a tree map, comparing the type of single-use bioreactor and company size, [B] an insightful grid representation based on scale of operation, area of application and type of cell culture, [C] heat map representation analyzing type of single-use bioreactor and area of application, and [D] a world map representation highlighting the regional distribution of players based on the location of headquarters. In addition, it presents details of the companies involved in the development of single-use bioreactors, providing information on their year of establishment, company size, and location of headquarters.
  • A detailed case study on the market landscape of different types of bioprocess controllers based on important parameters, such as scale of operation (laboratory, clinical, and commercial) , key features (scalability / ease to use, visual data display, remote accessibility, built-in system control sensors, expansive I/O compatibility and provisions for alarms / alerts) , compatibility with bioreactor system (stirred tank (glass), single use bioreactor, stirred tank (steel), fermenter, rocking motion) , mode of operation (batch, fed batch and perfusion) , and types of process controlled (cell cultivation and microbial fermentation) . In addition, the chapter presents details of companies involved in the development of bioprocess controllers, including information on their year of establishment, company size, and location of headquarters.

One of the key objectives of the report was to understand the primary growth drivers and estimate the potential future growth opportunities of single-use sensors. Based on multiple parameters, such as overall bioprocessing equipment market, and adoption rate of automation systems, we have developed informed estimates on the evolution of the market over the period 2021-2035. Our year-wise projections of the current and future opportunity have further been segmented on the basis of [A] type of sensor (conductivity, flow, pH, pressure and temperature) , [B] type of bioprocessing (upstream and downstream bioprocessing, and [C] key geographical regions (North America, Europe, Asia Pacific 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, Chapter Outlinesortraying different tracks of the anticipated industry growth. The opinions and insights presented in the report are backed by a deep understanding of key insights gathered from secondary research.

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:

  • What are the key features of single-use sensor systems?
  • Who are the leading players engaged in the development of single-use sensors?
  • What are the different application areas where single-use sensors can be used?
  • Who are the leading key opinion leaders engaged in the field of single-use sensors?
  • What are the key trends within the single-use sensors market?
  • 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 sensors market and its likely evolution in the short to mid-term and long term.

Chapter 3 provides a general introduction to single-use sensors, covering details related to the current trends in this domain. The chapter discusses the model of process control system and its purpose. In addition, the chapter highlights the role of sensors in the process control system and its applications, along with the benefits and challenges associated with single-use sensors.

Chapter 4 provides a detailed assessment of the overall market landscape of around 90 commercialized single-use sensors, based on a number of relevant parameters, such as type of sensor (conductivity, flow, pH, pressure and temperature), type of bioprocessing, measurement range, operating temperature, sterilization technique, material used and application area. In addition, the chapter presents details of the companies involved in the development of single-use sensors, including information on their year of establishment, company size, and location of headquarters.

Chapter 5 features a detailed competitiveness analysis of various types of single-use sensors, taking into consideration several relevant parameters, such as the product applicability (based on the type of processes controlled and applications) and product strength (based on the key features and sterilization technique used).

Chapter 6 features elaborate profiles of prominent players (shortlisted on the basis of number of products being offered) engaged in the development of single-use sensors. Each company profile features a brief overview of the company, information on its product portfolio, recent developments and an informed future outlook.

Chapter 7 includes a case study on pre-installed single use sensor systems and their analyses based on multiple parameters, including type of sensor, measuring range, operating temperature and applications. In addition, it provides details on developer landscape, including information on their year of establishment, company size, and location of headquarters.

Chapter 8 provides a case study on the market landscape of single-use bioreactors, based on a number of parameters, such as status of development (commercially available / under development), type of single-use bioreactor (stirred tank, pneumatically mixed, rocker / rotating, wave-induced, paddle sleeve, fixed-bed, hollow fiber, diffusion, orbitally shaken, and others), scale of operation (laboratory scale, pilot scale, and large scale), area of application (cancer research, drug discovery / toxicology testing, stem cell research, tissue engineering / regenerative medicine, and others), working volume, weight of bioreactor, stirrer speed, cell culture handled (mammalian, insect, microbial, viral, plant, bacterial, and others), and type of molecule (vaccine, monoclonal antibody, recombinant protein, stem cell, cell therapy, gene therapy, and others). In addition, it presents details of the companies involved in the development of single-use bioreactors, providing information on their year of establishment, company size, and location of headquarters.

Chapter 9 features a case study on the market landscape of different types of bioprocess controllers, based on important parameters, such as scale of operation (laboratory, clinical, and commercial), key features (scalability / ease to use, visual data display, remote accessibility, built-in system control sensors, expansive I/O compatibility and provisions for alarms / alerts), compatibility with the bioreactor systems (stirred tank (glass), single use bioreactor, stirred tank (steel), fermenter, rocking motion), mode of operation (batch, fed batch and perfusion), and type of process controlled (cell cultivation and microbial fermentation). In addition, the chapter presents details of the companies involved in the development of bioprocess controllers, including information on their year of establishment, company size, and location of headquarters.

Chapter 10 features an insightful market forecast analysis, highlighting the likely growth and future potential of the single-use sensors for bioprocessing market, for the period 2021-2035. In order to provide a detailed future outlook, our year-wise projections of the current and future opportunity have further been segmented on the basis of [A] type of sensor (conductivity, dissolved oxygen, flow, pH, pressure and temperature), [B] type of bioprocessing (upstream, and downstream bioprocessing), and [C] key geographical regions (North America, Europe, Asia Pacific and Rest of the World).

Chapter 11 is a summary of the overall report, which presents insights on the contemporary market trends and the likely evolution of the single-use sensors for bioprocessing market.

Chapter 12 is an appendix, which provides tabulated data and numbers for all the figures in the report.

Chapter 13 is an appendix, which contains the list of companies and organizations mentioned in the report.

TABLE OF CONTENTS

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

List Of Figures

  • Figure 3.1 Factors Affecting Manufacturing of Biologics
  • Figure 3.2 Overview of Controlled Parameters in Bioreactors
  • Figure 3.3 Basic Bioprocess Control Model
  • Figure 4.1 Single-use Sensors for Bioprocessing: Distribution by Type of Sensor
  • Figure 4.2 Single-use Sensors for Bioprocessing: Distribution by Type of Bioprocessing
  • Figure 4.3 Single-use Sensors for Bioprocessing: Distribution by Operating Temperature
  • Figure 4.4 Single-use Sensors for Bioprocessing: Distribution by Sterilization Technique
  • Figure 4.5 Single-use Sensors for Bioprocessing: Distribution by Sensor Calibration
  • Figure 4.6 Single-use Sensors for Bioprocessing: Distribution by Type of Material Used
  • Figure 4.7 Single-use Sensors for Bioprocessing: Distribution by Application Area
  • Figure 4.8 Single-use Sensors for Bioprocessing Developers: Distribution by Year of Establishment
  • Figure 4.9 Single-use Sensors for Bioprocessing Developers: Distribution by Company Size
  • Figure 4.10 Single-use Sensors for Bioprocessing Developers: Distribution by Location of Headquarters
  • Figure 5.1 Competitiveness Analysis: Flow Sensors
  • Figure 5.2 Competitiveness Analysis: Pressure Sensors
  • Figure 5.3 Competitiveness Analysis: pH Sensors
  • Figure 5.4 Competitiveness Analysis: Conductivity and Temperature Sensors
  • Figure 7.1 Pre-installed Single-use Sensors: Distribution by Type of Sensor
  • Figure 7.2 Pre-installed Single-use Sensors: Distribution by Operating Temperature
  • Figure 7.3 Pre-installed Single-use Sensors: Distribution by Sensor Calibration
  • Figure 7.4 Pre-installed Single-use Sensors: Distribution by Application Area
  • Figure 7.5 Pre-installed Single-use Sensor Developers: Distribution of Developers by Year of Establishment
  • Figure 7.6 Pre-installed Single-use Sensors: Distribution of Developers by Company Size
  • Figure 7.7 Pre-installed Single-use Sensors: Distribution of Developers by Location of Headquarters
  • Figure 8.1 Single-use Bioreactors: Distribution by Status of Development
  • Figure 8.2 Single-use Bioreactors: Distribution by Type of Single-Use Bioreactor
  • Figure 8.3 Single-use Bioreactors: Distribution by Scale of Operation
  • Figure 8.4 Single-use Bioreactors: Distribution by Area of Application
  • Figure 8.5 Single-use Bioreactors: Distribution by Working Volume
  • Figure 8.6 Single-use Bioreactors: Distribution by Weight of Bioreactor
  • Figure 8.7 Single-use Bioreactors: Distribution by Speed of Stirrer
  • Figure 8.8 Single-use Bioreactors: Distribution by Type of Cell Culture Handled
  • Figure 8.9 Single-use Bioreactors: Distribution by Type of Molecule
  • Figure 8.10 Single-use Bioreactor Developers: Distribution by Year of Establishment
  • Figure 8.11 Single-use Bioreactor Developers: Distribution by Company Size
  • Figure 8.12 Single-use Bioreactor Developers: Distribution by Location of Headquarters
  • Figure 8.13 Leading Manufacturers: Distribution by Number of Products
  • Figure 8.14 Tree Map Representation: Distribution by Type of Single-use Bioreactor and Company Size
  • Figure 8.15 Heat Map Representation: Distribution by Scale of Operation, Area of Application and Type of Cell Culture Handled
  • Figure 8.16 Heat Map Representation: Distribution by Type of Single-use Bioreactor and Area of Application
  • Figure 8.17 World Map Representation: Distribution by Location of Headquarters
  • Figure 9.1 Bioprocess Control Software: Distribution by Scale of Operation
  • Figure 9.2 Bioprocess Control Software: Distribution by Key Features
  • Figure 9.3 Bioprocess Control Software: Distribution by Compatibility with Bioprocessing Systems
  • Figure 9.4 Bioprocess Control Software: Distribution by Types of Processes Controlled
  • Figure 9.5 Bioprocess Control Software Developers: Distribution by Year of Establishment
  • Figure 9.6 Bioprocess Control Software Developers: Distribution by Company Size
  • Figure 9.7 Bioprocess Control Software Developers: Distribution by Location of Headquarters
  • Figure 9.8 Upstream Controllers: Distribution by Scale of Operation
  • Figure 9.9 Upstream Controllers: Distribution by Key Features
  • Figure 9.10 Upstream Controllers: Distribution by Compatibility with Bioreactor systems
  • Figure 9.11 Upstream Controllers: Distribution by Mode of Operation
  • Figure 9.12 Upstream Controllers: Distribution by Types of Processes Controlled
  • Figure 9.13 Upstream Controller Developers: Distribution by Year of Establishment
  • Figure 9.14 Upstream Controller Developers: Distribution by Company Size
  • Figure 9.15 Upstream Controller Developers: Distribution by Location of Headquarters
  • Figure 9.16 Downstream Controller Systems: Distribution by Scale of Operation
  • Figure 9.17 Downstream controller systems: Distribution by Key Features
  • Figure 9.18 Downstream Controller Systems: Distribution by Type of Bioprocessing System(s)
  • Figure 9.19 Downstream Controller Systems: Distribution by Mode of Operation
  • Figure 9.20 Downstream Controller Systems: Distribution by Application Area
  • Figure 9.21 Downstream Controller System Developers: Distribution by Year of Establishment
  • Figure 9.22 Downstream Controller System Developers: Distribution by Company Size
  • Figure 9.23 Downstream Controller System Developers: Distribution by Location of Headquarters
  • Figure 10.1 Global Single-use Sensors for Bioprocessing Market, 2021-2035 (USD Billion)
  • Figure 10.2 Global Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Sensor (USD Billion)
  • Figure 10.3 Single-use Sensors for Bioprocessing Market for Conductivity Sensors, 2021-2035 (USD Billion)
  • Figure 10.4 Single-use Sensors for Bioprocessing Market for Dissolved Oxygen Sensors, 2021-2035 (USD Billion)
  • Figure 10.5 Single-use Sensors for Bioprocessing Market for Flow Sensors, 2021-2035 (USD Billion)
  • Figure 10.6 Single-use Sensors for Bioprocessing Market for pH Sensors, 2021-2035 (USD Billion)
  • Figure 10.7 Single-use Sensors for Bioprocessing Market for Pressure Sensors, 2021-2035 (USD Billion)
  • Figure 10.8 Single-use Sensors for Bioprocessing Market for Temperature Sensors, 2021-2035 (USD Billion)
  • Figure 10.9 Global Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Type of Bioprocessing
  • Figure 10.10. Single-use Sensors for Bioprocessing Market for Downstream Bioprocessing, 2021-2035 (USD Billion)
  • Figure 10.11. Single-use Sensors for Bioprocessing Market for Upstream Bioprocessing, 2021-2035 (USD Billion)
  • Figure 10.12 Single-use Sensors for Bioprocessing Market, 2021-2035: Distribution by Key Geographical Regions (USD Billion)
  • Figure 10.13 Single-use Sensors for Bioprocessing Market in North America, 2021-2035 (USD Billion)
  • Figure 10.14 Single-use Sensors for Bioprocessing Market in Europe, 2021-2035 (USD Billion)
  • Figure 10.15 Single-use Sensors for Bioprocessing Market in Asia Pacific, 2021-2035 (USD Billion)
  • Figure 11.1 Concluding Remarks: Market Overview of Single-use Sensors for Bioprocessing
  • Figure 11.2 Concluding Remarks: Case Study on Single-use Bioreactors
  • Figure 11.3 Concluding Remarks: Case Study on Bioprocess Controllers and Automation Systems
  • Figure 11.4 Concluding Remarks: Market Forecast and Opportunity Analysis

List Of Tables

  • Table 4.1 Single-use Sensors for Bioprocessing: List of Products
  • Table 4.2 Single-use Sensors for Bioprocessing: Information on Sterilization Technique
  • Table 4.3 Single-use Sensors for Bioprocessing: Information on Sensor Calibration, Type of Material Used and Application Area
  • Table 4.4 Single-use Sensors for Bioprocessing Product Developers: Information of Year of Establishment, Company Size and Location of Headquarters
  • Table 6.1 Applied Biosensors: Company Snapshot
  • Table 6.2 Applied Biosensors: Single-use Sensor Product Portfolio
  • Table 6.3 Applied Biosensors: Recent Developments and Future Outlook
  • Table 6.4 Levitronix: Company Snapshot
  • Table 6.5 Levitronix: Single-use Sensor Product Portfolio
  • Table 6.6 Levitronix: Recent Developments and Future Outlook
  • Table 6.7 Malema Engineering: Company Snapshot
  • Table 6.8 Malema Engineering: Single-use Sensor Product Portfolio
  • Table 6.9 Malema Engineering: Recent Developments and Future Outlook
  • Table 6.7 Masterflex (acquired by Avantor): Company Snapshot
  • Table 6.8 Masterflex (acquired by Avantor): Single-use Sensor Product Portfolio
  • Table 6.9 Masterflex (acquired by Avantor): Recent Developments and Future Outlook
  • Table 6.10 Parker Hannifin: Company Snapshot
  • Table 6.11 Parker Hannifin: Single-use Sensor Product Portfolio
  • Table 6.12 Parker Hannifin: Recent Developments and Future Outlook
  • Table 6.13 PendoTECH (acquired by METTLER TOLEDO): Company Snapshot
  • Table 6.14 PendoTECH (acquired by METTLER TOLEDO): Single-use Sensor Product Portfolio
  • Table 6.15 PendoTECH (acquired by METTLER TOLEDO): Recent Developments and Future Outlook
  • Table 6.16 PreSens Precision Sensing: Company Snapshot
  • Table 6.17 PreSens Precision Sensing: Single-use Sensor Product Portfolio
  • Table 6.18 PreSens Precision Sensing: Recent Developments and Future Outlook
  • Table 6.19 Finesse Solutions (acquired by Thermo Fisher Scientific): Company Snapshot
  • Table 6.20 Finesse Solutions (acquired by Thermo Fisher Scientific): Single-use Sensor Product Portfolio
  • Table 6.21 Finesse Solutions (acquired by Thermo Fisher Scientific): Recent Developments and Future Outlook
  • Table 7.1 Pre-installed Single-use Sensors for Bioprocessing: Information on Single-use Sensor Systems
  • Table 7.2 Pre-installed Single-use Sensor Systems for Bioprocessing: Information on Sensor Calibration and Application Area
  • Table 7.3 Pre-installed Single-use Sensors for Bioprocessing Product Developers: Information of Year of Establishment, Company Size and Location of Headquarters
  • Table 8.1 Single-use Bioreactors: Information on Status of Development, Type of Bioreactor and Scale of Operation
  • Table 8.2 Single-use Bioreactors: Information on Working Volume, Stirrer Speed, and Weight, Length, Width, Height and Diameter of Bioreactor
  • Table 8.3 Single-use Bioreactors: Information on Type of Cell Culture Handled
  • Table 8.3 Single-use Bioreactors: Information on Type of Molecule
  • Table 8.4 Single-use Bioreactors: Information on Area of Application and Advanced Display / Control Features
  • Table 8.5 Single-use Bioreactors: List of Manufacturers
  • Table 9.1 Bioprocess Control Software: Information on Stage of Bioprocess and Scale of Operation
  • Table 9.2 Bioprocess Control Software: Information on Key Features, Compatibility with Bioprocessing Systems and Types of Processes Controlled
  • Table 9.3 Bioprocess Control Software Developers: Information of Year of Establishment, Company Size and Location of Headquarters
  • Table 9.4 Upstream Controllers: Information on Dimensions and Scale of Operation
  • Table 9.5 Upstream Controllers: Information on Key Features, Mode of Operation, Compatibility with Bioreactor Systems and Types of Processes Controlled
  • Table 9.6 Upstream Controller Developers: Information of Year of Establishment, Company Size and Location of Headquarters
  • Table 9.7 Downstream Controller Systems: Information on Dimensions, Type of Controllers and Scale of Operation
  • Table 9.8 Downstream Controller Systems: Information on Key Features, Type of Bioprocessing System(s) Involved, Mode of Operation and Application Area
  • Table 9.9 Downstream Controller System Developers: Information of Year of Establishment, Company Size and Location of Headquarters
  • Table 12.1 Single-use Sensors for Bioprocessing: Distribution by Type of Sensor
  • Table 12.2 Single-use Sensors for Bioprocessing: Distribution by Type of Bioprocessing
  • Table 12.3 Single-use Sensors for Bioprocessing: Distribution by Operating Temperature
  • Table 12.4 Single-use Sensors for Bioprocessing: Distribution by Sterilization Technique
  • Table 12.5 Single-use Sensors for Bioprocessing: Distribution by Sensor Calibration
  • Table 12.6 Single-use Sensors for Bioprocessing: Distribution by Type of Material Used
  • Table 12.7 Single-use Sensors for Bioprocessing: Distribution by Application Area
  • Table 12.8 Single-use Sensors for Bioprocessing Developers: Distribution of Developers by Year of Establishment
  • Table 12.9 Single-use Sensors for Bioprocessing Developers: Distribution of Developers by Company Size
  • Table 12.10 Single-use Sensors for Bioprocessing Developers: Distribution of Developers by Location of Headquarters
  • Table 12.11 Pre-installed Single-use Sensors: Distribution by Type of Sensor
  • Table 12.12 Pre-installed Single-use Sensors: Distribution by Operating Temperature
  • Table 12.13 Pre-installed Single-use Sensors: Distribution by Sensor Calibration
  • Table 12.14 Pre-installed Single-use Sensors: Distribution by Application Area
  • Table 12.15 Pre-installed Single-use Sensor Developers: Distribution of Developers by Year of Establishment
  • Table 12.16 Pre-installed Single-use Sensors: Distribution of Developers by Company Size
  • Table 12.17 Pre-installed Single-use Sensors: Distribution of Developers by Location of Headquarters
  • Table 12.18 Single-Use Bioreactors: Distribution by Status of Development
  • Table 12.19 Single-use Bioreactors: Distribution by Type of Single-use Bioreactor
  • Table 12.20 Single-use Bioreactors: Distribution by Scale of Operation
  • Table 12.21 Single-use Bioreactors: Distribution by Area of Application
  • Table 12.22 Single-use Bioreactors: Distribution by Working Volume
  • Table 12.23 Single-use Bioreactors: Distribution by Weight of Bioreactor
  • Table 12.24 Single-use Bioreactors: Distribution by Speed of Stirrer
  • Table 12.25 Single-use Bioreactors: Distribution by Type of Cell Culture Handled
  • Table 12.26 Single-use Bioreactors: Distribution by Type of Molecule
  • Table 12.27 Single-use Bioreactor Developers: Distribution by Year of Establishment
  • Table 12.28 Single-use Bioreactor Developers: Distribution by Company Size
  • Table 12.29 Single-use Bioreactor Developers: Distribution by Location of Headquarters
  • Table 12.30 Single-use Bioreactor Developers: Distribution by Number of Products
  • Table 12.31 Tree Map Representation: Distribution by Type of Single-use Bioreactor and Company Size
  • Table 12.32 Heat Map Representation: Distribution by Scale of Operation, Area of Application and Type of Cell Culture Handled
  • Table 12.33 Heat Map Representation: Distribution by Type of Single-use Bioreactor and Area of Application
  • Table 12.34 World Map Representation: Distribution by Location of Headquarters
  • Table 12.35 Bioprocess Control Software: Distribution by Stage of Bioprocess
  • Table 12.36 Bioprocess Control Software: Distribution by Scale of Operation
  • Table 12.37 Bioprocess Control Software: Distribution by Key Features
  • Table 12.38 Bioprocess Control Software: Distribution by Compatibility with Bioprocessing Systems
  • Table 12.39 Bioprocess Control Software: Distribution by Types of Processes Controlled
  • Table 12.40 Bioprocess Control Software Developers: Distribution by Year of Establishment
  • Table 12.41 Bioprocess Control Software Developers: Distribution by Company Size
  • Table 12.42 Bioprocess Control Software Developers: Distribution by Location of Headquarters
  • Table 12.43 Upstream Controllers: Distribution by Scale of Operation
  • Table 12.44 Upstream Controllers: Distribution by Key Features
  • Table 12.45 Upstream Controllers: Distribution by Compatibility with Bioreactor systems
  • Table 12.46 Upstream Controllers: Distribution by Mode of Operation
  • Table 12.47 Upstream Controllers: Distribution by Types of Processes Controlled
  • Table 12.48 Upstream Controller Developers: Distribution by Year of Establishment
  • Table 12.49 Upstream Controller Developers: Distribution by Company Size
  • Table 12.50 Upstream Controller Developers: Distribution by Location of Headquarters
  • Table 12.51 Downstream Controller Systems: Distribution by Scale of Operation
  • Table 12.52 Downstream controller systems: Distribution by Key Features
  • Table 12.53 Downstream Controller Systems: Distribution by Type of Bioprocessing System(s)
  • Table 12.54 Downstream Controller Systems: Distribution by Mode of Operation
  • Table 12.55 Downstream Controller Systems: Distribution by Application Area
  • Table 12.56 Downstream Controller System Developers: Distribution by Year of Establishment
  • Table 12.57 Downstream Controller System Developers: Distribution by Company Size
  • Table 12.58 Downstream Controller System Developers: Distribution by Location of Headquarters
  • Table 12.59 Global Single-use Sensors for Bioprocessing Market, 2021-2035 (USD Billion)
  • Table 12.60 Single-use Sensors for Bioprocessing Market for Conductivity Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.61 Single-use Sensors for Bioprocessing Market for Dissolved Oxygen Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.62 Single-use Sensors for Bioprocessing Market for Flow Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.63 Single-use Sensors for Bioprocessing Market for pH Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.64 Single-use Sensors for Bioprocessing Market for Pressure Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.65 Single-use Sensors for Bioprocessing Market for Temperature Sensors, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.66 Single-use Sensors for Bioprocessing Market for Upstream Processing, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.67 Single-use Sensors for Bioprocessing Market for Downstream Processing, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.68 Single-use Sensors for Bioprocessing Market in North America, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.69 Single-use Sensors for Bioprocessing Market in Europe, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)
  • Table 12.70 Single-use Sensors for Bioprocessing Market in Asia Pacific and Rest of the World, Conservative, Base and Optimistic Scenarios 2021-2035 (USD Billion)

List Of Companies

The following companies and organizations have been mentioned in the report.

  • 1. 3Dnamics
  • 2. Aber Instruments
  • 3. Agilitech
  • 4. Applied Biosensors
  • 5. Applikon Biotechnology (acquired by Getinge)
  • 6. ARTeSYN BioSolutions
  • 7. Automated Control Concepts (ACC)
  • 8. B-CULTURE
  • 9. TSNS-biotech
  • 10. BIONET
  • 11. Biosan
  • 12. BlueSens
  • 13. Broadley-James
  • 14. Celartia
  • 15. Cell Culture Company
  • 16. Cellexus
  • 17. Celltainer Biotech
  • 18. CelVivo
  • 19. CerCell
  • 20. CESCO Bioengineering
  • 21. Cytiva
  • 22. Distek
  • 23. EirGenix
  • 24. Emerson
  • 25. Eppendorf
  • 26. Esco Aster
  • 27. Finesse Solutions (acquired by Thermo Fisher Scientific)
  • 28. Flotek Industries
  • 29. Flownamics
  • 30. Hamilton
  • 31. High Purity New England
  • 32. ILS Automation
  • 33. INFORS HT
  • 34. INTEGRA
  • 35. Kuhner shaker
  • 36. LAMBDA Laboratory Instruments Levitronix
  • 37. LFB Biomanufacturing
  • 38. Malema Engineering
  • 39. Masterflex
  • 40. Merck MilliporeSigma
  • 41. METTLER TOLEDO
  • 42. OmniBRx Biotechnologies
  • 43. optek-Danulat
  • 44. Pall Corporation
  • 45. Parker Hannifin
  • 46. PBS Biotech
  • 47. PendoTECH
  • 48. PerfuseCell
  • 49. PIERRE GUERIN
  • 50. Polestar Technologies
  • 51. Premas Biotech
  • 52. PreSens Precision Sensing
  • 53. ProlifeCell
  • 54. RealBio Technology
  • 55. Rentschler Biopharma
  • 56. Repligen
  • 57. REPROCELL
  • 58. Sartorius
  • 59. SATAKE MultiMix
  • 60. Sensirion
  • 61. Sepragen
  • 62. Solaris Biotech
  • 63. SONOTEC
  • 64. Strain Measurement Devices
  • 65. Synthecon
  • 66. Thermo Fisher Scientific
  • 67. Univercells
  • 68. VERDOT Ips