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The global discrete analyzers market is expected to enjoy a valuation of US$ 1.5 Billion in the year 2023, and further expand at a CAGR of 5.2% to reach a valuation of ~US$ 2.6 Billion by the year 2033. According to a recent study by Future Market Insights, discrete analyzer systems in the product segment are leading the market with a share of about 47.6% in the year 2022, within the global market.
Market Outlook:
Data Points | Market Insights |
---|---|
Market Value 2022 | US$ 1.5 Billion |
Market Value 2033 | US$ 2.6 Billion |
CAGR 2023 to 2033 | 5.2% |
Market Share of Top 5 Countries | 55.5% |
Key Market Players | Thermofisher Scientific Inc., Seal Analytical, Skalar Analytical B.V., Chinchilla Scientific, SYSTEA S.p.a, Astoria-Pacific, Inc., Siemens Industry, Inc., NECi Superior Enzymes, Abbott Laboratories, Roche Holding AG, KPM Analytics |
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To preserve dependable and safe water sources and to get rid of any potential health and environmental problems, it is crucial to constantly test and monitor water quality.
Environmental water quality monitoring attempts to deliver the information necessary for defending the environment against harmful biological impacts from chemical contamination brought on by anthropogenic point sources and diffuse emissions. There is a need for more effective methods for demonstrating causal relationships between chemical and ecological assessments as well as ways of detecting pollutants specific to river basins.
The challenge for a successful amendment and implementation of the European Water Framework Directive is to propose more specific strategies given the dynamics of chemical invention, manufacture, consumption, use, disposal, and resultant emission into the aquatic environment. Discrete analyzers are an important tool in environmental water analysis, which will drive the discrete analyzers market.
Measuring the amounts of nutrients in drinking water, wastewater, and soil samples is crucial for protecting aquatic habitats and maintaining the cleanliness and safety of drinking water sources. Utility companies and environmental laboratories must routinely test elemental phosphorus and nitrogen in sewage water, in addition to several other pollution indications, to ensure discharge streams adhere to statutory limitations.
Waterborne infections continue to be the primary cause of morbidity and mortality in humans around the world. Pathogens, chemical pollutants, and waterborne diseases can all be avoided by the use of discrete analyzer technology.
Thus, owing to the forenamed factors, the global discrete analyzers market is expected to grow at a CAGR of 5.2 % during the forecast period from 2023 to 2033.
The demand for water filtration has risen dramatically due to industrialization, urbanization, and ongoing population development. These factors lead to the contamination of fresh water. There is also a major global water scarcity problem.
One of the main causes of consumer concern over water quality and demand for water filtration is the release of contaminated water containing harmful substances into the environment. In developing nations, strict water quality monitoring is necessary.
As a result, governments are putting pressure on device companies to develop instruments that perform tests on samples for water analysis. Corporations are thus investing in discrete analyzers.
Controlling the brewing quality while producing beer requires analysis of the malt, wort, and beer. Discrete analyzer technology ensures good product quality and throughput while performing multiparameter analysis for wine, malt, beer, and food and beverage utilities while lowering costs, waste, and hands-on sample time.
Consumers today are driven by a sense of exploration or by a fear of missing out. When it comes to food and beverages, they are always looking for new experiences. Food and beverage makers must maintain the quality of their products to retain consumer involvement.
Modern technology is being applied in the food and beverage industry by discrete analyzers. Food's distinctive qualities, such as colour, taste, and flavour, are all greatly influenced by a number of chemical factors, including pH, sulfite, sugars, organic acids, nitrogen compounds, phenols, titratable acidity, and volatile acids. As a result, the malolactic process requires constant monitoring of these factors. To raise the calibre of food, discrete analyzers are employed. Using discrete analyzers can help remove some impurities while also testing for product quality and safety without compromising any of the product's crucial sensory qualities.
Discrete analyzers can be used in diverse applications such as fruit and vegetable juices (apple, carrot, etc.), cheeses, ice cream, butter, fermented milk, microfiltered milk, skimmed or low-lactose dairy products, non-alcoholic beers, wines, ciders, and many other food and beverage segments.
The increasing awareness regarding global climate change, along with the rapid urbanization witnessed in countries in various regions, is leading to increasing demand for a smoothly functioning water and wastewater infrastructure.
The introduction of legislation and regulations in the market by regulatory authorities of several regions regarding water and wastewater management and use is ensuring the growth of the industry and also creating a significant market opportunity for discrete analyzer manufacturers across the world.
This can be considered as an opportunistic factor for the manufacturers operating within the discrete analyzers market.
The most comprehensive technique for assessing the quality of water sample is discrete analysis. The employees must be skilled in order to use this strategy. Many research groups lack the qualified personnel needed to operate these testing devices. Using discrete analyzers requires a great deal of accuracy and precision.
Accordingly, it is anticipated that other challenges and a shortage of skilled personnel will hinder the use of these devices.
In contrast to continuous flow analyzers, discrete analyzers have a lot more moving components, making them mechanically more challenging. This method also occasionally necessitates using a lot of reagent for the analyzer.
Research laboratories need continuous, high-quality customer service for them to keep their high-quality service. These requirements are becoming increasingly questionable because of cost apprehensions.
Therefore, it is highly challenging for research laboratories to strike a balance between cost and quality objectives and requirements. The problem was assumed to be solved by laboratory automation, which has been widely adopted with varying degrees of automation in all contemporary laboratories.
The mentioned factors collectively propose an adverse effect on the developmental growth of the discrete analyzers market.
The USA accounted for around 89.6% market share in the North America discrete analyzers market in 2022, and a similar trend is expected over the forecast period.
The main reason for North America to lead the region section is due to the higher adoption of advanced technologies in healthcare facilities and a larger number of discrete analyzer manufacturers in the region. Continuous research and development activities along with increasing demand for automated discrete analyzers in the region drive the growth of the discrete analyzers market. North America is expected to be the most lucrative region in the discrete analyzers market and this has boosted the availability of products in the USA discrete analyzer market.
Germany is set to exhibit a CAGR of nearly 5.2% in the European discrete analyzers market during the forecast period. In 2022, Germany held the highest market share of about 22.8% 2022 in the Europe discrete analyzer market.
Germany has the 3rd most lucrative medtech market in the world, following the United States and Japan. According to the International Trade Administration (2022), the medical device market in Germany is one of the most profitable health and medical marketplaces in the world, accounting for around USD 35.8 billion annually or 25.6% of the whole European market. As a result, the discrete analyzer industry in Germany is quite lucrative.
India held approximately 41.3% market share in the South Asia and Pacific discrete analyzers market in 2022. It is projected to display growth at a lucrative CAGR of 5.6% during the forecast period. Government involvement in environmental monitoring in response to growing health concerns combined with the commercialization of environmental testing services will fuel industry expansion. This situation has aided in the discrete analyzers market rise in India.
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The discrete analyzer systems segment in the product category of the discrete analyzers market is expected to present high growth at a CAGR of 5.5% by the end of the forecast period, with a projected market share of about 49.0 % in the global market in 2033.
Discrete analyzer technology offers great product quality, precise measurement, and productivity while lowering cost, waste, and hands-on sample time has a positive impact on the market for discrete analyzers. Discrete analyzers are used for measurement assessment for food and beverage, environment water, industrial water, and water utilities.
The bench-top discrete analyzers in the modality segment have become more and more popular, accounting for the greatest proportion of 77.4% in 2022. The bench-top analyzer fully automates sample testing and is perfect for laboratories that need many different tests performed quickly on a variety of samples. Particularly for analyzing environmental materials, such as water, soil, and plant extracts.
With 35.3% of the market share, environmental testing labs segment in the end user category dominated the discrete analyzer market in 2022. The government’s goal is to broaden the scope of pollution monitoring, not to replace or displace current laboratories.
Discrete analyzers can discover and quantify patterns while allowing for the monitoring of a wide range of locations using sensors of varying accuracy. The environmental authorities will of course need to conduct a thorough investigation into serious contamination incidents. The discrete analyzer technology can help with the early detection of such issues.
The discrete analyzer technique will contribute to expanding the reach of environmental laboratories.
To strengthen their presence around the globe and improve their business strategies, the key players are involved in various product launches, expansions, collaborations, and mergers and acquisitions. These are the top key promotional strategies adopted by the key players in the discrete analyzers market.
Similarly, recent developments have been tracked by the team at Future Market Insights related to companies in the discrete analyzers space, which are available in the full report.
Attribute | Details |
---|---|
Forecast Period | 2023 to 2033 |
Historical Data Available for | 2017 to 2022 |
Market Analysis | US$ Billion for Value & Volume (Units) |
Key Regions Covered | North America, Latin America, Europe, East Asia, South Asia and Pacific, and Middle East & Africa |
Key Countries Covered | USA, Canada, Brazil, Mexico, Germany, Italy, France, UK, Spain, BENELUX, Russia, Nordic Countries, China, Japan, South Korea, India, ASEAN, ANZ, GCC Countries, Türkiye, North Africa, and South Africa |
Key Market Segments Covered | Product, Modality, End User, and Region |
Key Companies Profiled |
|
Pricing | Available upon Request |
The discrete analyzers market is worth US$ 1.5 billion in 2023.
The discrete analyzers market is projected to thrive at a 5.2% CAGR through 2033.
The discrete analyzers market is predicted to surpass US$ 2.6 billion by 2033.
The United States accounted for nearly 89.6% of the discrete analyzers market share in 2022.
The discrete analyzers market’s top 5 countries’ market share is nearly 55.5%.
1. Executive Summary | Discrete Analyzers Market 1.1. Global Market Outlook 1.2. Demand Side Trends 1.3. Supply-Side Side Trends 1.4. Analysis and Recommendations 2. Market Overview 2.1. Market Coverage / Taxonomy 2.2. Market Definition / Scope / Limitations 2.3. Inclusions and Exclusions Market 3. Key Market Trends 3.1. Key Trends Impacting the Market 3.2. Product Innovation / Development Trends 4. Key Success Factors 4.1. Product Adoption / Usage Analysis 4.2. Product USPs / Features 4.3. Strategic Promotional Strategies 5. Global Market Volume (‘000 Units) Demand Analysis 2017–2022 and Forecast, 2023 to 2033 5.1. Historical Market Volume (‘000 Units) Analysis, 2017–2022 5.2. Current and Future Market Volume (‘000 Units) Projections, 2023 to 2033 5.2.1. Y-o-Y Growth Trend Analysis 6. Global Market- Pricing Analysis 6.1. Global Average Pricing Analysis Benchmark 6.2. Pricing Assumptions 7. Global Market Demand (in Value or Size in US$ Million) Analysis 2017 to 2033 and Forecast, 2023 to 2033 7.1. Historical Market Value (US$ Million) Analysis 2017 to 2033 7.2. Current and Future Market Value (US$ Million) Projections, 2023 to 2033 7.2.1. Y-o-Y Growth Trend Analysis 7.2.2. Absolute $ Opportunity Analysis 8. Market Background 8.1. Macro-Economic Factors 8.1.1. Global GDP Growth Outlook 8.1.2. Global Healthcare Spending Outlook 8.1.3. Industry Value Added Factors 8.2. Forecast Factors - Relevance & Impact 8.2.1. Top Companies Historical Growth 8.2.2. Accurate, precise measurements 8.2.3. Increasing pollution incidents 8.2.4. Increasing adoption due to rapid results 8.2.5. Reduced Labour costs 8.3. Value Chain 8.3.1. List of Manufacturers 8.3.2. List of Suppliers/Distributors 8.3.3. List of Probable End Users 8.3.4. Average Margins 8.4. COVID-19 Crisis – Impact Assessment 8.4.1. Current Statistics 8.4.2. Short-Mid-Long Term Outlook 8.5. Market Dynamics 8.5.1. Drivers 8.5.2. Restraints 8.5.3. Opportunity Analysis 8.6. Overview of methods to analyze Nutrients in Waste water 9. Global Market Analysis 2017 to 2033 and Forecast 2023 to 2033, By Product 9.1. Introduction / Key Findings 9.2. Historical Market Size (US$ Million) and Volume (‘000 Units) Analysis By Product Type, 2017 to 2033 9.3. Current and Future Market Size (US$ Million) and Volume (‘000 Units) Analysis and Forecast By Product Type, 2023 to 2033 9.3.1. Systems 9.3.1.1. <140 Tests 9.3.1.2. 150- 200 Tests Capacity 9.3.1.3. 201-450 Tests Capacity 9.3.1.4. 410-600 and More Tests Capacity 9.3.2. Consumables 9.3.2.1. Cuvettes 9.3.2.2. Reagents 9.3.2.3. Coils 9.3.3. Software 9.4. Market Attractiveness Analysis By Product Type 10. Global Market Analysis 2017 to 2033 and Forecast 2023 to 2033, By Modality 10.1. Introduction / Key Findings 10.2. Historical Market Size (US$ Million) and Analysis by Application, 2017 to 2033 10.3. Current and Future Market Size (US$ Million) Analysis and Forecast by Modality, 2023 to 2033 10.3.1. Standalone 10.3.2. Bench Top 10.4. Market Attractiveness Analysis by Application 11. Global Market Analysis 2017 to 2033 and Forecast 2023 to 2033, By End-User 11.1. Introduction / Key Findings 11.2. Historical Market Size (US$ Million) and Analysis by End User, 2017 to 2033 11.3. Current and Future Market Size (US$ Million) and Analysis and Forecast By End-User, 2023 to 2033 11.3.1. Waste Water Plants 11.3.2. General Testing Labs 11.3.3. Environmental Testing Labs 11.3.4. Agriculture and Food Testing Labs 11.3.5. Pharmaceutical Companies 11.3.6. Government and Academic Institutes and Laboratories 11.3.7. Contract Research Organization 11.4. Market Attractiveness Analysis by Range 12. Global Market Analysis 2017 to 2033 and Forecast 2023 to 2033, by Region 12.1. Introduction 12.2. Historical Market Size (US$ Million) Analysis By Region, 2017 to 2033 12.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Region, 2023 to 2033 12.3.1. North America 12.3.2. Latin America 12.3.3. Europe 12.3.4. East Asia 12.3.5. South Asia and Pacific 12.3.6. Middle East & Africa 12.4. Market Attractiveness Analysis By Region 13. North America Market Analysis 2017 to 2033 and Forecast 2023 to 2033 13.1. Introduction 13.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 13.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Market Taxonomy, 2023 to 2033 13.3.1. By Country 13.3.1.1. USA 13.3.1.2. Canada 13.3.2. By Product Type 13.3.3. By Modality 13.3.4. By End-User 13.3.5. By Region 13.4. Market Attractiveness Analysis 13.4.1. By Country 13.4.2. By Product Type 13.4.3. By Modality 13.4.4. By End-User 13.5. Market Trends 13.6. Key Market Participants - Intensity Mapping 13.7. Drivers and Restraints - Impact Analysis 14. Latin America Market Analysis 2017 to 2033 and Forecast 2023 to 2033 14.1. Introduction 14.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 14.3. Current and Future Market Size (US$ Million Analysis and Forecast By Market Taxonomy, 2023 to 2033 14.3.1. By Country 14.3.1.1. Brazil 14.3.1.2. Mexico 14.3.1.3. Rest of Latin America 14.3.2. By Product Type 14.3.3. By Modality 14.3.4. By End-User 14.4. Market Attractiveness Analysis 14.4.1. By Country 14.4.2. By Product Type 14.4.3. By Modality 14.4.4. By End-User 14.5. Market Trends 14.6. Key Market Participants - Intensity Mapping 14.7. Drivers and Restraints - Impact Analysis 15. Europe Market Analysis 2017 to 2033 and Forecast 2023 to 2033 15.1. Introduction 15.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 15.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Market Taxonomy, 2023 to 2033 15.3.1. By Country 15.3.1.1. Germany 15.3.1.2. Italy 15.3.1.3. France 15.3.1.4. United Kingdom 15.3.1.5. Spain 15.3.1.6. BENELUX 15.3.1.7. Russia 15.3.1.8. Nordic Countries 15.3.1.9. Rest of Europe 15.3.1.9.1. By Product Type 15.3.1.9.2. By Modality 15.3.1.9.3. By End-User 15.4. Market Attractiveness Analysis 15.4.1.1.1. By Country 15.4.1.1.2. By Product Type 15.4.1.1.3. By Modality 15.4.1.1.4. By End-User 15.5. Market Trends 15.6. Key Market Participants - Intensity Mapping 15.7. Drivers and Restraints - Impact Analysis 16. East Asia Market Analysis 2017 to 2033 and Forecast 2023 to 2033 16.1. Introduction 16.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 16.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Market Taxonomy, 2023 to 2033 16.3.1. By Country 16.3.1.1. China 16.3.1.2. Japan 16.3.1.3. South Korea 16.3.2. By Product Type 16.3.3. By Modality 16.3.4. By End-User 16.4. Market Attractiveness Analysis 16.4.1. By Country 16.4.2. By Product Type 16.4.3. By Modality 16.4.4. By End-User 16.5. Market Trends 16.6. Key Market Participants - Intensity Mapping 16.7. Drivers and Restraints - Impact Analysis 17. South Asia and Pacific Market Analysis 2017 to 2033 and Forecast 2023 to 2033 17.1. Introduction 17.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 17.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Market Taxonomy, 2023 to 2033 17.3.1. By Country 17.3.1.1. India 17.3.1.2. ASEA 17.3.1.3. ANZ 17.3.1.4. Rest of South Asia and Pacific 17.3.2. By Product Type 17.3.3. By Modality 17.3.4. By End-User 17.4. Market Attractiveness Analysis 17.4.1. By Country 17.4.2. By Product Type 17.4.3. By Modality 17.4.4. By End-User 17.5. Market Trends 17.6. Key Market Participants - Intensity Mapping 17.7. Drivers and Restraints - Impact Analysis 18. Middle East and Africa Market Analysis 2017 to 2033 and Forecast 2023 to 2033 18.1. Introduction 18.2. Historical Market Size (US$ Million) Analysis By Market Taxonomy, 2017 to 2033 18.3. Current and Future Market Size (US$ Million) Analysis and Forecast By Market Taxonomy, 2023 to 2033 18.3.1. By Country 18.3.1.1. GCC Countries 18.3.1.2. Türkiye 18.3.1.3. North Africa 18.3.1.4. South Africa 18.3.1.5. Rest of Middle East and Africa 18.3.2. By Product Type 18.3.3. By Modality 18.3.4. By End-User 18.4. Market Attractiveness Analysis 18.4.1. By Country 18.4.2. By Product Type 18.4.3. By Modality 18.4.4. By End-User 18.5. Market Trends 18.6. Key Market Participants - Intensity Mapping 18.7. Drivers and Restraints - Impact Analysis 19. Emerging Countries Market Analysis 19.1. Introduction 19.1.1. Market Value Proportion Analysis, By Key Countries 19.1.2. Global Vs. Country Growth Comparison 19.2. USA Market Analysis 19.2.1. By Product Type 19.2.2. By Modality 19.2.3. By End-User 19.3. Canada Market Analysis 19.3.1. By Product Type 19.3.2. By Modality 19.3.3. By End-User 19.4. Mexico Market Analysis 19.4.1. By Product Type 19.4.2. By Modality 19.4.3. By End-User 19.5. Brazil Market Analysis 19.5.1. By Product Type 19.5.2. By Modality 19.5.3. By End-User 19.6. Germany Market Analysis 19.6.1. By Product Type 19.6.2. By Modality 19.6.3. By End-User 19.7. Italy Market Analysis 19.7.1. By Product Type 19.7.2. By Modality 19.7.3. By End-User 19.8. United Kingdom Market Analysis 19.8.1. By Product Type 19.8.2. By Modality 19.8.3. By End-User 19.9. Spain Market Analysis 19.9.1. By Product Type 19.9.2. By Modality 19.9.3. By End-User 19.10. BENELUX Market Analysis 19.10.1. By Product Type 19.10.2. By Modality 19.10.3. By End-User 19.11. Russia Market Analysis 19.11.1. By Product Type 19.11.2. By Modality 19.11.3. By End-User 19.12. Nordic Countries Market Analysis 19.12.1. By Product Type 19.12.2. By Modality 19.12.3. By End-User 19.13. China Market Analysis 19.13.1. By Product Type 19.13.2. By Modality 19.13.3. By End-User 19.14. Japan Market Analysis 19.14.1. By Product Type 19.14.2. By Modality 19.14.3. By End-User 19.15. South Korea Market Analysis 19.15.1. By Product Type 19.15.2. By Modality 19.15.3. By End-User 19.16. India Market Analysis 19.16.1. By Product Type 19.16.2. By Modality 19.16.3. By End-User 19.17. ASEA Market Analysis 19.17.1. By Product Type 19.17.2. By Modality 19.17.3. By End-User 19.18. ANZ Market Analysis 19.18.1. By Product Type 19.18.2. By Modality 19.18.3. By End-User 19.19. GCC Countries Market Analysis 19.19.1. By Product Type 19.19.2. By Modality 19.19.3. By End-User 19.20. Turkey Market Analysis 19.20.1. By Product Type 19.20.2. By Modality 19.20.3. By End-User 19.21. South Africa Market Analysis 19.21.1. By Product Type 19.21.2. By Modality 19.21.3. By End-User 19.22. North Africa Market Analysis 19.22.1. By Product Type 19.22.2. By Modality 19.22.3. By End-User 20. Market Structure Analysis 20.1. Market Analysis by Tier of Companies (Discrete Analyzers) 20.2. Market Concentration 20.3. Market Share Analysis of Top Players 20.4. Market Presence Analysis 20.4.1. Regional Footprint by Players 20.4.2. Product Footprint by Players 20.4.3. Channel Foot Print by Players 21. Competition Analysis 21.1. Competition Dashboard 21.2. Competition Benchmarking 21.3. Competition Deep Dive 21.3.1. Thermofisher Scientific Inc. 21.3.1.1. Overview 21.3.1.2. Product Portfolio 21.3.1.3. Profitability by Market Segments (Product/Channel/Region) 21.3.1.4. Sales Footprint 21.3.1.5. Strategy Overview 21.3.2. Seal Analytical 21.3.2.1. Overview 21.3.2.2. Product Portfolio 21.3.2.3. Profitability by Market Segments (Product/Channel/Region) 21.3.2.4. Sales Footprint 21.3.2.5. Strategy Overview 21.3.3. Skalar Analytical B.V. 21.3.3.1. Overview 21.3.3.2. Product Portfolio 21.3.3.3. Profitability by Market Segments (Product/Channel/Region) 21.3.3.4. Sales Footprint 21.3.3.5. Strategy Overview 21.3.4. Chinchilla Scientific 21.3.4.1. Overview 21.3.4.2. Product Portfolio 21.3.4.3. Profitability by Market Segments (Product/Channel/Region) 21.3.4.4. Sales Footprint 21.3.4.5. Strategy Overview 21.3.5. SYSTEA S.p.a 21.3.5.1. Overview 21.3.5.2. Product Portfolio 21.3.5.3. Profitability by Market Segments (Product/Channel/Region) 21.3.5.4. Sales Footprint 21.3.5.5. Strategy Overview 21.3.6. Astoria-Pacific, Inc. 21.3.6.1. Overview 21.3.6.2. Product Portfolio 21.3.6.3. Profitability by Market Segments (Product/Channel/Region) 21.3.6.4. Sales Footprint 21.3.6.5. Strategy Overview 21.3.7. Siemens Industry, Inc. 21.3.7.1. Overview 21.3.7.2. Product Portfolio 21.3.7.3. Profitability by Market Segments (Product/Channel/Region) 21.3.7.4. Sales Footprint 21.3.7.5. Strategy Overview 21.3.8. NECi Superior Enzymes 21.3.8.1. Overview 21.3.8.2. Product Portfolio 21.3.8.3. Profitability by Market Segments (Product/Channel/Region) 21.3.8.4. Sales Footprint 21.3.8.5. Strategy Overview 21.3.9. Abbot 21.3.9.1. Overview 21.3.9.2. Product Portfolio 21.3.9.3. Profitability by Market Segments (Product/Channel/Region) 21.3.9.4. Sales Footprint 21.3.9.5. Strategy Overview 21.3.10. Roche 21.3.10.1. Overview 21.3.10.2. Product Portfolio 21.3.10.3. Profitability by Market Segments (Product/Channel/Region) 21.3.10.4. Sales Footprint 21.3.10.5. Strategy Overview 21.3.11. KPM Analytics 21.3.11.1. Overview 21.3.11.2. Product Portfolio 21.3.11.3. Profitability by Market Segments (Product/Channel/Region) 21.3.11.4. Sales Footprint 21.3.11.5. Strategy Overview 22. Assumptions and Acronyms Used 23. Research Methodology
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