Global Flow Cytometry Market Size, Share & Industry Trends Analysis Report By Application (Academic & Clinical and Diagnostic), By End User, By Technology (Cell Based and Bead Based), By Component, By Regional Outlook and Forecast, 2022 – 2028

Global Flow Cytometry Market Size, Share & Industry Trends Analysis Report By Application (Academic & Clinical and Diagnostic), By End User, By Technology (Cell Based and Bead Based), By Component, By Regional Outlook and Forecast, 2022 – 2028

The Global Flow Cytometry Market size is expected to reach $7.7 billion by 2028, rising at a market growth of 8.3% CAGR during the forecast period.

With regard to describing and distinguishing various cell types within a heterogeneous population of cells, measuring cell size and volume, and determining the purity of separated subpopulations, flow cytometry is a commonly utilized technique. It allows the simultaneous evaluation of several parameters for an individual cell.

It is used to quantify the amount of fluorescence that fluorescently-labeled antibodies emit when they identify ligand proteins that bind to particular compounds found in cells, such as DNA and propidium iodide. Following the staining step, cells are placed in tubes or microtiter plates and incubated with unlabeled or fluorescently-labeled antibodies before being analyzed on a flow cytometer.

A laboratory test called flow cytometry is used to examine the properties of cells or particles. A sample of cells or other particles is pumped into a flow cytometer system while suspended in the liquid. In less than a minute, a computer can analyze and process about 10,000 cells. Analyzing the activation of cell surface or intracellular molecules is made easier by flow cytometry. It helps evaluate the purity of isolated subpopulations and is used to describe and characterize various types of cells across a heterogeneous cell population.

The market is being driven by increased R&D efforts by many prominent players for the creation of multicolor assays as well as cutting-edge analytical reagents. The market for flow cytometry has experienced rapid expansion as a result of the rising prevalence of chronic and infectious disorders. Typical samples range from various cell populations isolated from tissues to a cell line producing Green Fluorescent Protein.

The sample must be a single-cell suspension, which is the most important condition for effective and efficient flow cytometry analysis. This makes sure that each cell is examined separately. Cancer and immunodeficiency are two conditions that are frequently diagnosed using flow cytometry. One of the elements anticipated to propel the flow cytometry market in the coming years is the rising prevalence of certain disorders.

COVID-19 Impact Analysis

The COVID-19 pandemic had a favorable effect on the prospects for the flow cytometry business during the initial COVID-19 outbreak. The rising application of reagents in research and clinical trials has boosted the market share of flow cytometry reagents and therefore the use of the flow cytometry approach. For instance, in March 2020, Cytek Biosciences Inc. provided support to doctors and researchers who were examining the effects of the COVID-19 virus on human immune systems. COVID-19 patients had lower T- and B-cell frequencies than recovered donors or healthy donors.

Market Growth Factors

A Rise In The Adoption Of The Flow Cytometry Approach In Academia And Research

The increasing incidence and prevalence of HIV/AIDS and cancer worldwide, the growing use of flow cytometry techniques in academic and research settings, the expansion of public-private initiatives within the fields of microbiology and immuno-oncology research, technological advancements, the increasing integration of AI platforms into flow cytometry workflows, and improvements in flow cytometry software all contribute to the market's growth. During the drug research and development procedures, flow cytometry has become a crucial technique for safety as well as exploratory objectives.

A Significant Expansion In The Number Of Applications Of Flow Cytometry

There is a rise in the number of applications of flow cytometry. Immunophenotyping is the procedure that uses the cytometer the most frequently. With the use of this method, groups of cells in a dataset consisting of blood, bone marrow, or lymph can be located and measured. These cell subsets are identified by fluorescently tagging population-specific proteins on the cell surface. Immunophenotyping aids in the clinical lab diagnosis of hematological malignancies such as lymphomas and leukemia. Additionally, in cell sorting applications, a customized flow cytometer called a cell sorter may physically separate target cells into different collection tubes. Each cell is interrogated and characterized by the cytometer as it moves through the laser.

Market Restraining Factors

High Cost Along With The Availability Of Alternatives Across The Market

Most end customers, including clinical laboratories, major research institutions, and pharmaceutical firms, need a lot of flow cytometry equipment to do several research projects at once. As a result, the initial cost related to the purchase and maintenance of these devices rises significantly. Budget constraints make it difficult for research and academic laboratories to purchase such tools. The total cost of the acquisition of these instruments also rises as a result of maintenance charges and a number of other indirect expenses.

Component Outlook

Based on Component, the Flow Cytometry Market is segmented into Instruments, Reagents and consumables, Software, and Services. In 2021, the reagents and consumables segment garnered a substantial revenue share of the flow cytometry market. The innovation and distribution of high-quality assays and reagents for certain applications as well as end users' ongoing need for flow cytometry reagents are two factors that are propelling the growth of this segment.

Technology Outlook

On the basis of Technology, the Flow Cytometry Market is bifurcated into Cell based flow cytometry and Bead based flow cytometry. In 2021, the cell-based flow cytometry segment procured the biggest revenue share of the flow cytometry market. Due to the ability to assess compound activity towards molecular targets while surrounded by living cells, cell-based flow cytometry is being employed more frequently in the drug discovery process.

Application Outlook

By the Application, the Flow Cytometry Market is divided into Academic and clinical applications and Diagnostic applications. In 2021, the academic & clinical applications segment witnessed the highest revenue share of the flow cytometry market. The growth of the segment is rapidly rising as a result of increased research into academic and clinical applications of flow cytometry. Moreover, with the increasing number of initiatives and improvements in the educational infrastructures of several countries all over the world, the utilization of flow cytometry in educational facilities is also increasing.

End-User Outlook

Based on End-User, the Flow Cytometry Market is segregated into Hospitals, Medical schools & clinical testing labs, Commercial organizations, Academic institutions, and Others. In 2021, the hospitals segment witnessed a significant revenue share of the flow cytometry market. The growing demand for affordable diagnosis of target diseases, like cancer, is one of the major factors that are propelling the growth of this segment of the market. In addition, the integration of several advanced technologies and innovations in hospitals all over the world is increasing.

Regional Outlook

Region-Wise, the Flow Cytometry Market is analyzed across North America, Europe, Asia-Pacific, and LAMEA. In 2021, North America accounted for the largest revenue share of the flow cytometry market. Rapid technological improvements, rising R&D spending, an expanding patent pool, and an increase in applications all contribute to the growth of the flow cytometry market in North America. In addition, regional countries are early adopters of new and cutting-edge technologies, which is also boosting the adoption of flow cytometry technology in regional hospitals and other applications. The regional market is flourishing owing to these factors.

The major strategies followed by the market participants are Acquisitions. Based on the Analysis presented in the Cardinal matrix; Thermo Fisher Scientific, Inc. and Danaher Corporation are the forerunners in the Flow Cytometry Market. Companies such as Becton Dickinson and Company, Agilent Technologies, Inc., Bio-Rad Laboratories, Inc. are some of the key innovators in Flow Cytometry Market.

The market research report covers the analysis of key stake holders of the market. Key companies profiled in the report include Agilent Technologies, Inc., Thermo Fisher Scientific, Inc., Danaher Corporation, Becton Dickinson and Company, BioMérieux S.A., Bio-Rad Laboratories, Inc., DiaSorin S.p.A., Miltenyi Biotec B.V. & Co. KG, Sartorius AG, and Sysmex Corporation.

Recent Strategies Deployed in Flow Cytometry Market

Partnership, Collaboration and Agreement:

Aug-2022: BD collaborated with Labcorp, a leader in life sciences. Following this collaboration, the companies aimed to leverage the prospects within the pharmaceutical industry in order to manufacture new companion diagnostics with the capability to enhance patient outcomes.

Product Launch and Product Expansion:

Mar-2022: Danaher Corporation's subsidiary, Beckman Coulter Life Sciences rolled out the CellMek SPS, a robust solution for manual sample preparation. The new solution aimed to offer on-demand processing for multiple sample types with the objective to aid laboratories in increasing their capabilities. In addition, it would also reduce the time-consuming burden of manual workflows for lab staff to prevent errors.

Jun-2021: Thermo Fisher unveiled the Invitrogen Attune CytPix Flow Cytometer, an enhanced imaging enhanced flow cytometer. The new solution would integrate acoustic focusing flow cytometry technology and a high-speed camera in order to provide improved imaging flow cytometry. Moreover, it also marks a cornerstone in the company's vision to fulfill customer demand by offering to provide an additional sample as well as data quality control through an easy and simple format.

Sep-2020: Agilent Technologies rolled out Agilent NovoCyte Penteon, a flow cytometer with five lasers and sensitivity. The new product aimed to offer increased UV laser excitation capabilities and multicolor flow cytometry assays accommodation. In addition, the new NovoCyte Penteon would also carry further the legacy of cytometry performance matched simplicity and intuitiveness of user experience.

Jun-2020: Sysmex America released the XF-1600 flow cytometer. The new XF-1600 functions in tandem with the company's PS-10 Sample Preparation System in order to automate the whole antibody staining, flow cytometry analysis, and incubation process. It would ensure a higher confidence level among the produced output.

Acquisition, Joint Venture and Merger:

Apr-2022: bioMerieux completed its acquisition of Specific Diagnostics, the developer of a rapid antimicrobial susceptibility test system. Following this acquisition, the company aimed to allow laboratories and clinicians to further improve and enhance patient outcomes as well as expand antimicrobial stewardship through its extensive distribution network.

Feb-2022: BD completed its acquisition of Cytognos, a subsidiary of Vitro. With this acquisition, the company aimed to expand its blood cancer diagnostics portfolio as well as its offerings for immune assessment tests and informatics and clinician and care provider requirements with the aim to comply with the demands of patients.

Feb-2021: Thermo Fisher Scientific took over Propel Labs, a subsidiary of SIDIS. Through this acquisition, the company aimed to integrate Propel's highly skilled staff into its facility in order to leverage their additional flow cytometry expertise, engineering strength, and R&D capabilities intending to improve its cell therapy research and cell analysis business.

Jan-2021: Thermo Fisher Scientific acquired Phitonex, a developer of the next generation of fluorescent labels and instrumentation. This acquisition aimed to allow the company to provide better flow cytometry along with greater imaging multiplexing capabilities with the aim to comply with the changing demands of customers for cell and protein analysis research.

Approvals and Trials:

Oct-2020: BD received the US FDA approval for its Integrated BD FACSDuet Sample Preparation System-built BD FACSLyric Flow Cytometer. BD FACSDuet Sample Preparation System aimed to offer improved capabilities to BD offerings of clinical flow cytometry solutions to provide a pre-analytical system.

Scope of the Study

Market Segments covered in the Report:

By Application

  • Academic & Clinical
  • Diagnostic
By End User
  • Commercial Organizations
  • Hospitals
  • Academic Institutions
  • Medical Schools & Clinical Testing Labs
  • Others
By Technology
  • Cell Based
  • Bead Based
By Component
  • Instruments
  • Reagents & Consumables
  • Software
  • Services
By Geography
  • North America
  • US
  • Canada
  • Mexico
  • Rest of North America
  • Europe
  • Germany
  • UK
  • France
  • Russia
  • Spain
  • Italy
  • Rest of Europe
  • Asia Pacific
  • China
  • Japan
  • India
  • South Korea
  • Singapore
  • Malaysia
  • Rest of Asia Pacific
  • LAMEA
  • Brazil
  • Argentina
  • UAE
  • Saudi Arabia
  • South Africa
  • Nigeria
  • Rest of LAMEA
Companies Profiled
  • Agilent Technologies, Inc.
  • Thermo Fisher Scientific, Inc.
  • Danaher Corporation
  • Becton Dickinson and Company
  • BioMérieux S.A.
  • Bio-Rad Laboratories, Inc.
  • DiaSorin S.p.A.
  • Miltenyi Biotec B.V. & Co. KG
  • Sartorius AG
  • Sysmex Corporation
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Chapter 1. Market Scope & Methodology
1.1 Market Definition
1.2 Objectives
1.3 Market Scope
1.4 Segmentation
1.4.1 Global Flow Cytometry Market, by Application
1.4.2 Global Flow Cytometry Market, by End User
1.4.3 Global Flow Cytometry Market, by Technology
1.4.4 Global Flow Cytometry Market, by Component
1.4.5 Global Flow Cytometry Market, by Geography
1.5 Methodology for the research
Chapter 2. Market Overview
2.1 Introduction
2.1.1 Overview
2.1.1.1 Market composition and scenario
2.2 Key Factors Impacting the Market
2.2.1 Market Drivers
2.2.2 Market Restraints
Chapter 3. Competition Analysis - Global
3.1 KBV Cardinal Matrix
3.2 Recent Industry Wide Strategic Developments
3.2.1 Partnerships, Collaborations and Agreements
3.2.2 Product Launches and Product Expansions
3.2.3 Acquisition and Mergers
3.2.4 Acquisition and Mergers
3.3 Top Winning Strategies
3.3.1 Key Leading Strategies: Percentage Distribution (2018-2022)
Chapter 4. Global Flow Cytometry Market by Application
4.1 Global Academic & Clinical Market by Region
4.2 Global Diagnostic Market by Region
Chapter 5. Global Flow Cytometry Market by End User
5.1 Global Commercial Organizations Market by Region
5.2 Global Hospitals Market by Region
5.3 Global Academic Institutions Market by Region
5.4 Global Medical Schools & Clinical Testing Labs Market by Region
5.5 Global Other End User Market by Region
Chapter 6. Global Flow Cytometry Market by Technology
6.1 Global Cell Based Market by Region
6.2 Global Bead Based Market by Region
Chapter 7. Global Flow Cytometry Market by Component
7.1 Global Instruments Market by Region
7.2 Global Reagents & Consumables Market by Region
7.3 Global Software Market by Region
7.4 Global Services Market by Region
Chapter 8. Global Flow Cytometry Market by Region
8.1 North America Flow Cytometry Market
8.1.1 North America Flow Cytometry Market by Application
8.1.1.1 North America Academic & Clinical Market by Country
8.1.1.2 North America Diagnostic Market by Country
8.1.2 North America Flow Cytometry Market by End User
8.1.2.1 North America Commercial Organizations Market by Country
8.1.2.2 North America Hospitals Market by Country
8.1.2.3 North America Academic Institutions Market by Country
8.1.2.4 North America Medical Schools & Clinical Testing Labs Market by Country
8.1.2.5 North America Other End User Market by Country
8.1.3 North America Flow Cytometry Market by Technology
8.1.3.1 North America Cell Based Market by Country
8.1.3.2 North America Bead Based Market by Country
8.1.4 North America Flow Cytometry Market by Component
8.1.4.1 North America Instruments Market by Country
8.1.4.2 North America Reagents & Consumables Market by Country
8.1.4.3 North America Software Market by Country
8.1.4.4 North America Services Market by Country
8.1.5 North America Flow Cytometry Market by Country
8.1.5.1 US Flow Cytometry Market
8.1.5.1.1 US Flow Cytometry Market by Application
8.1.5.1.2 US Flow Cytometry Market by End User
8.1.5.1.3 US Flow Cytometry Market by Technology
8.1.5.1.4 US Flow Cytometry Market by Component
8.1.5.2 Canada Flow Cytometry Market
8.1.5.2.1 Canada Flow Cytometry Market by Application
8.1.5.2.2 Canada Flow Cytometry Market by End User
8.1.5.2.3 Canada Flow Cytometry Market by Technology
8.1.5.2.4 Canada Flow Cytometry Market by Component
8.1.5.3 Mexico Flow Cytometry Market
8.1.5.3.1 Mexico Flow Cytometry Market by Application
8.1.5.3.2 Mexico Flow Cytometry Market by End User
8.1.5.3.3 Mexico Flow Cytometry Market by Technology
8.1.5.3.4 Mexico Flow Cytometry Market by Component
8.1.5.4 Rest of North America Flow Cytometry Market
8.1.5.4.1 Rest of North America Flow Cytometry Market by Application
8.1.5.4.2 Rest of North America Flow Cytometry Market by End User
8.1.5.4.3 Rest of North America Flow Cytometry Market by Technology
8.1.5.4.4 Rest of North America Flow Cytometry Market by Component
8.2 Europe Flow Cytometry Market
8.2.1 Europe Flow Cytometry Market by Application
8.2.1.1 Europe Academic & Clinical Market by Country
8.2.1.2 Europe Diagnostic Market by Country
8.2.2 Europe Flow Cytometry Market by End User
8.2.2.1 Europe Commercial Organizations Market by Country
8.2.2.2 Europe Hospitals Market by Country
8.2.2.3 Europe Academic Institutions Market by Country
8.2.2.4 Europe Medical Schools & Clinical Testing Labs Market by Country
8.2.2.5 Europe Other End User Market by Country
8.2.3 Europe Flow Cytometry Market by Technology
8.2.3.1 Europe Cell Based Market by Country
8.2.3.2 Europe Bead Based Market by Country
8.2.4 Europe Flow Cytometry Market by Component
8.2.4.1 Europe Instruments Market by Country
8.2.4.2 Europe Reagents & Consumables Market by Country
8.2.4.3 Europe Software Market by Country
8.2.4.4 Europe Services Market by Country
8.2.5 Europe Flow Cytometry Market by Country
8.2.5.1 Germany Flow Cytometry Market
8.2.5.1.1 Germany Flow Cytometry Market by Application
8.2.5.1.2 Germany Flow Cytometry Market by End User
8.2.5.1.3 Germany Flow Cytometry Market by Technology
8.2.5.1.4 Germany Flow Cytometry Market by Component
8.2.5.2 UK Flow Cytometry Market
8.2.5.2.1 UK Flow Cytometry Market by Application
8.2.5.2.2 UK Flow Cytometry Market by End User
8.2.5.2.3 UK Flow Cytometry Market by Technology
8.2.5.2.4 UK Flow Cytometry Market by Component
8.2.5.3 France Flow Cytometry Market
8.2.5.3.1 France Flow Cytometry Market by Application
8.2.5.3.2 France Flow Cytometry Market by End User
8.2.5.3.3 France Flow Cytometry Market by Technology
8.2.5.3.4 France Flow Cytometry Market by Component
8.2.5.4 Russia Flow Cytometry Market
8.2.5.4.1 Russia Flow Cytometry Market by Application
8.2.5.4.2 Russia Flow Cytometry Market by End User
8.2.5.4.3 Russia Flow Cytometry Market by Technology
8.2.5.4.4 Russia Flow Cytometry Market by Component
8.2.5.5 Spain Flow Cytometry Market
8.2.5.5.1 Spain Flow Cytometry Market by Application
8.2.5.5.2 Spain Flow Cytometry Market by End User
8.2.5.5.3 Spain Flow Cytometry Market by Technology
8.2.5.5.4 Spain Flow Cytometry Market by Component
8.2.5.6 Italy Flow Cytometry Market
8.2.5.6.1 Italy Flow Cytometry Market by Application
8.2.5.6.2 Italy Flow Cytometry Market by End User
8.2.5.6.3 Italy Flow Cytometry Market by Technology
8.2.5.6.4 Italy Flow Cytometry Market by Component
8.2.5.7 Rest of Europe Flow Cytometry Market
8.2.5.7.1 Rest of Europe Flow Cytometry Market by Application
8.2.5.7.2 Rest of Europe Flow Cytometry Market by End User
8.2.5.7.3 Rest of Europe Flow Cytometry Market by Technology
8.2.5.7.4 Rest of Europe Flow Cytometry Market by Component
8.3 Asia Pacific Flow Cytometry Market
8.3.1 Asia Pacific Flow Cytometry Market by Application
8.3.1.1 Asia Pacific Academic & Clinical Market by Country
8.3.1.2 Asia Pacific Diagnostic Market by Country
8.3.2 Asia Pacific Flow Cytometry Market by End User
8.3.2.1 Asia Pacific Commercial Organizations Market by Country
8.3.2.2 Asia Pacific Hospitals Market by Country
8.3.2.3 Asia Pacific Academic Institutions Market by Country
8.3.2.4 Asia Pacific Medical Schools & Clinical Testing Labs Market by Country
8.3.2.5 Asia Pacific Other End User Market by Country
8.3.3 Asia Pacific Flow Cytometry Market by Technology
8.3.3.1 Asia Pacific Cell Based Market by Country
8.3.3.2 Asia Pacific Bead Based Market by Country
8.3.4 Asia Pacific Flow Cytometry Market by Component
8.3.4.1 Asia Pacific Instruments Market by Country
8.3.4.2 Asia Pacific Reagents & Consumables Market by Country
8.3.4.3 Asia Pacific Software Market by Country
8.3.4.4 Asia Pacific Services Market by Country
8.3.5 Asia Pacific Flow Cytometry Market by Country
8.3.5.1 China Flow Cytometry Market
8.3.5.1.1 China Flow Cytometry Market by Application
8.3.5.1.2 China Flow Cytometry Market by End User
8.3.5.1.3 China Flow Cytometry Market by Technology
8.3.5.1.4 China Flow Cytometry Market by Component
8.3.5.2 Japan Flow Cytometry Market
8.3.5.2.1 Japan Flow Cytometry Market by Application
8.3.5.2.2 Japan Flow Cytometry Market by End User
8.3.5.2.3 Japan Flow Cytometry Market by Technology
8.3.5.2.4 Japan Flow Cytometry Market by Component
8.3.5.3 India Flow Cytometry Market
8.3.5.3.1 India Flow Cytometry Market by Application
8.3.5.3.2 India Flow Cytometry Market by End User
8.3.5.3.3 India Flow Cytometry Market by Technology
8.3.5.3.4 India Flow Cytometry Market by Component
8.3.5.4 South Korea Flow Cytometry Market
8.3.5.4.1 South Korea Flow Cytometry Market by Application
8.3.5.4.2 South Korea Flow Cytometry Market by End User
8.3.5.4.3 South Korea Flow Cytometry Market by Technology
8.3.5.4.4 South Korea Flow Cytometry Market by Component
8.3.5.5 Singapore Flow Cytometry Market
8.3.5.5.1 Singapore Flow Cytometry Market by Application
8.3.5.5.2 Singapore Flow Cytometry Market by End User
8.3.5.5.3 Singapore Flow Cytometry Market by Technology
8.3.5.5.4 Singapore Flow Cytometry Market by Component
8.3.5.6 Malaysia Flow Cytometry Market
8.3.5.6.1 Malaysia Flow Cytometry Market by Application
8.3.5.6.2 Malaysia Flow Cytometry Market by End User
8.3.5.6.3 Malaysia Flow Cytometry Market by Technology
8.3.5.6.4 Malaysia Flow Cytometry Market by Component
8.3.5.7 Rest of Asia Pacific Flow Cytometry Market
8.3.5.7.1 Rest of Asia Pacific Flow Cytometry Market by Application
8.3.5.7.2 Rest of Asia Pacific Flow Cytometry Market by End User
8.3.5.7.3 Rest of Asia Pacific Flow Cytometry Market by Technology
8.3.5.7.4 Rest of Asia Pacific Flow Cytometry Market by Component
8.4 LAMEA Flow Cytometry Market
8.4.1 LAMEA Flow Cytometry Market by Application
8.4.1.1 LAMEA Academic & Clinical Market by Country
8.4.1.2 LAMEA Diagnostic Market by Country
8.4.2 LAMEA Flow Cytometry Market by End User
8.4.2.1 LAMEA Commercial Organizations Market by Country
8.4.2.2 LAMEA Hospitals Market by Country
8.4.2.3 LAMEA Academic Institutions Market by Country
8.4.2.4 LAMEA Medical Schools & Clinical Testing Labs Market by Country
8.4.2.5 LAMEA Other End User Market by Country
8.4.3 LAMEA Flow Cytometry Market by Technology
8.4.3.1 LAMEA Cell Based Market by Country
8.4.3.2 LAMEA Bead Based Market by Country
8.4.4 LAMEA Flow Cytometry Market by Component
8.4.4.1 LAMEA Instruments Market by Country
8.4.4.2 LAMEA Reagents & Consumables Market by Country
8.4.4.3 LAMEA Software Market by Country
8.4.4.4 LAMEA Services Market by Country
8.4.5 LAMEA Flow Cytometry Market by Country
8.4.5.1 Brazil Flow Cytometry Market
8.4.5.1.1 Brazil Flow Cytometry Market by Application
8.4.5.1.2 Brazil Flow Cytometry Market by End User
8.4.5.1.3 Brazil Flow Cytometry Market by Technology
8.4.5.1.4 Brazil Flow Cytometry Market by Component
8.4.5.2 Argentina Flow Cytometry Market
8.4.5.2.1 Argentina Flow Cytometry Market by Application
8.4.5.2.2 Argentina Flow Cytometry Market by End User
8.4.5.2.3 Argentina Flow Cytometry Market by Technology
8.4.5.2.4 Argentina Flow Cytometry Market by Component
8.4.5.3 UAE Flow Cytometry Market
8.4.5.3.1 UAE Flow Cytometry Market by Application
8.4.5.3.2 UAE Flow Cytometry Market by End User
8.4.5.3.3 UAE Flow Cytometry Market by Technology
8.4.5.3.4 UAE Flow Cytometry Market by Component
8.4.5.4 Saudi Arabia Flow Cytometry Market
8.4.5.4.1 Saudi Arabia Flow Cytometry Market by Application
8.4.5.4.2 Saudi Arabia Flow Cytometry Market by End User
8.4.5.4.3 Saudi Arabia Flow Cytometry Market by Technology
8.4.5.4.4 Saudi Arabia Flow Cytometry Market by Component
8.4.5.5 South Africa Flow Cytometry Market
8.4.5.5.1 South Africa Flow Cytometry Market by Application
8.4.5.5.2 South Africa Flow Cytometry Market by End User
8.4.5.5.3 South Africa Flow Cytometry Market by Technology
8.4.5.5.4 South Africa Flow Cytometry Market by Component
8.4.5.6 Nigeria Flow Cytometry Market
8.4.5.6.1 Nigeria Flow Cytometry Market by Application
8.4.5.6.2 Nigeria Flow Cytometry Market by End User
8.4.5.6.3 Nigeria Flow Cytometry Market by Technology
8.4.5.6.4 Nigeria Flow Cytometry Market by Component
8.4.5.7 Rest of LAMEA Flow Cytometry Market
8.4.5.7.1 Rest of LAMEA Flow Cytometry Market by Application
8.4.5.7.2 Rest of LAMEA Flow Cytometry Market by End User
8.4.5.7.3 Rest of LAMEA Flow Cytometry Market by Technology
8.4.5.7.4 Rest of LAMEA Flow Cytometry Market by Component
Chapter 9. Company Profiles
9.1 Becton, Dickinson and Company
9.1.1 Company Overview
9.1.2 Financial Analysis
9.1.3 Segmental and Regional Analysis
9.1.4 Research & Development Expense
9.1.5 Recent strategies and developments:
9.1.5.1 Partnerships, Collaborations, and Agreements:
9.1.5.2 Acquisition and Mergers:
9.1.5.3 Approvals and Trials:
9.2 Thermo Fisher Scientific, Inc.
9.2.1 Company Overview
9.2.2 Financial Analysis
9.2.3 Segmental and Regional Analysis
9.2.4 Research & Development Expense
9.2.5 Recent strategies and developments:
9.2.5.1 Product Launches and Product Expansions:
9.2.5.2 Acquisition and Mergers:
9.3 Danaher Corporation
9.3.1 Company Overview
9.3.2 Financial Analysis
9.3.3 Segmental and Regional Analysis
9.3.4 Research & Development Expense
9.3.5 Recent strategies and developments:
9.3.5.1 Product Launches and Product Expansions:
9.4 Agilent Technologies, Inc.
9.4.1 Company Overview
9.4.2 Financial Analysis
9.4.3 Segmental and Regional Analysis
9.4.4 Research & Development Expense
9.4.5 Recent strategies and developments:
9.4.5.1 Product Launches and Product Expansions:
9.4.5.2 Acquisition and Mergers:
9.5 BioMérieux S.A.
9.5.1 Company Overview
9.5.2 Financial Analysis
9.5.3 Segmental and Regional Analysis
9.5.4 Research & Development Expenses
9.5.5 Recent strategies and developments:
9.5.5.1 Acquisition and Mergers:
9.6 Bio-Rad laboratories, Inc.
9.6.1 Company Overview
9.6.2 Financial Analysis
9.6.3 Segmental and Regional Analysis
9.6.4 Research & Development Expenses
9.7 DiaSorin S.p.A.
9.7.1 Company Overview
9.7.2 Financial Analysis
9.7.3 Regional Analysis
9.7.4 Research & Development Expenses
9.8 Miltenyi Biotech B.V. & Co. KG
9.8.1 Company Overview
9.9 Sartorius AG
9.9.1 Company Overview
9.10. Sysmex Corporation
9.10.1 Company Overview
9.10.2 Financial Analysis
9.10.3 Regional Analysis
9.10.4 Research & Development Expense
9.10.5 Recent strategies and developments:
9.10.5.1 Product Launches and Product Expansions:

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