#Crosslinking Agent Market Trends
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Crosslinking Agent Market Share, Size, Future Demand, and Emerging Trends
Market Overview
The crosslinking agent market generated USD 10,207.3 million in 2023, which is projected to increase at a CAGR of 7.4% to attain USD 16,491.4 million by 2030. This is because crosslinking agents perform better, and there is a growing need for a variety of coatings.
The growing emphasis on sustainability and eco-friendly solutions is leading to the development of original cross-linking agents with a lower environmental impact.
Materials with enhanced qualities, such as strength, heat resistance, and durability, are required by industries including electronics, aerospace, and automation. Improved physical qualities are provided by these cross-linking, which are required for long-term heat resistance and durability in applications including medical devices, foam, pipes, cables, wires, and other PE applications.
These crosslinking agents do not produce any pollutants and release very low amounts of volatile organic chemicals. These agents are becoming common in a variety of applications, including wood finishing and automotive coatings.
These agents are used to improve the mechanical strength, chemical resistance, and thermal stability of polymers. In addition, the market's projected expansion is credited to the growing need for water-based crosslinking agents.
The production of bonds by condensation and free-radical polymerization eliminates most issues during usage, which is why the chemical crosslinking technique is mostly opted for.
Key Insights
The amino category held the largest market share, of 40%, in 2023.
This is due to the exceptional crosslinking capabilities and compatibility with a broad range of polymers offered by amino compounds, such as amino resins and amino silanes.
Specialized and advanced crosslinking agents, such as amino-based ones, have been introduced as a result of the ongoing research and development in amino chemistry.
The isocyanate category is expected to show the fastest growth in the market during the expected duration, owing to the growing application of these variants in a range of coating applications, including high-performance, ornamental, appliance, and automotive coatings.
Industrial coating is predicted to show the higher CAGR, of 8%, during the forecast period due to their wide usage in industries such as construction and automotive.
The industrial sector places a high priority on product quality and regulatory compliance, which propels the need for crosslinking agents to adhere to the strict specifications.
These agents increase the mechanical characteristics, chemical resistance, and lifespan of the materials used in various industries.
The decorative category holds the larger market share due to the usage of these coatings in in high volumes in commercial, residential, industrial, and institutional buildings.
The need for crosslinking agents in decorative coatings has increased as a result of the middle class's growing population and disposable income.
The APAC region is expected to grow at the fastest rate in the next few years, with China accounting for the largest share. This is attributed to its expanding economy and the growing automotive, electricals, and manufacturing sectors.
Governments’ encouragement programs for industry, increasing R&D spending, and a growing emphasis on environment-friendly solutions all contribute to the regional market's expansion.
Europe accounted for 20% of the revenue share in 2023 due to the growing construction industry, especially housing.
BASF, which has its headquarters and manufacturing plants in the region, announced in 2023 that it will increase the amount of isocyanate it now produces and increase its manufacturing capacity to approximately 600,000 metric tons annually.
Source: P&S Intelligence
#Crosslinking Agent Market Share#Crosslinking Agent Market Size#Crosslinking Agent Market Growth#Crosslinking Agent Market Applications#Crosslinking Agent Market Trends
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Film Forming Starches Market: Analyzing the Production Scenario and Demand Dynamics in Global Markets
The film forming starches market has emerged as a significant sector within the global starch industry, driven by the growing demand for sustainable, eco-friendly, and biodegradable alternatives across various industries. Film-forming starches are polymers derived from natural starch sources like corn, potato, cassava, and rice. These starches are gaining traction in multiple applications, from food packaging and coatings to pharmaceuticals, cosmetics, and agriculture, due to their renewable nature and potential for reducing environmental impact.
Production Scenario
The production of film-forming starches involves processing starch from natural sources through various techniques such as hydrolysis, esterification, and crosslinking. These processes enhance the properties of starch, enabling it to form films that are both flexible and resistant to moisture. The production process can be complex, as it requires maintaining the integrity of the starch molecules while modifying their physical properties to ensure film formation.
Leading producers of film-forming starches are concentrated in countries with a strong agricultural base, including the U.S., China, India, and several nations in Europe. Corn is the most common source of starch due to its abundant supply and cost-effectiveness. However, manufacturers are increasingly turning to other crops like cassava and potatoes, particularly in regions where these crops are more prevalent.
With the global shift toward sustainability, several manufacturers are exploring ways to produce biodegradable starch-based films that replace traditional plastics. Research and development efforts are also focusing on improving the mechanical properties of starch films, such as strength, elasticity, and water resistance, which are key factors for expanding their use in commercial applications.
Demand Dynamics in Global Markets
The demand for film-forming starches is being driven by several macroeconomic trends, including the growing emphasis on eco-friendly packaging, the rise of the clean-label movement in the food industry, and increasing consumer awareness about environmental issues. In particular, the food packaging sector has been one of the largest end-users of film-forming starches, as these films offer a biodegradable and non-toxic alternative to petroleum-based plastics.
In the food industry, starch-based films are used for packaging fresh produce, bakery items, and snacks. These films provide an effective barrier against moisture, oxygen, and other external factors, which helps to preserve food quality and extend shelf life. Moreover, they can be used in single-use applications such as edible packaging, which is gaining popularity as an alternative to plastic wrappers.
The pharmaceutical industry is also witnessing significant growth in the demand for film-forming starches. In this sector, starches are used to make coatings for tablets and capsules, improving the ease of swallowing and masking unpleasant tastes. Biodegradable starch films are considered a promising solution for controlled-release formulations, enhancing the therapeutic efficacy of medicines.
Another important market segment for film-forming starches is cosmetics, where they are used in products like lotions, creams, and shampoos as film-forming agents. These starches help create a smooth, protective layer on the skin and hair, offering moisturization and enhancing product stability.
Agriculture is also benefiting from the applications of starch-based films, especially for controlled-release fertilizers and crop protection products. Starch films can be designed to break down over time, releasing active ingredients in a controlled manner, which leads to improved crop yields and reduced environmental impact.
Regional Market Insights
The demand for film-forming starches varies significantly across regions, depending on factors like agricultural production, industrial development, and consumer preferences. North America and Europe are mature markets for film-forming starches, with significant demand driven by established industries such as food packaging, pharmaceuticals, and cosmetics.
Asia Pacific, particularly China and India, is emerging as a major market for these starch-based products. The region is witnessing rapid growth in the food processing and packaging sectors, as well as the adoption of eco-friendly alternatives in response to the increasing environmental concerns among consumers and regulatory authorities.
Latin America and the Middle East are also expected to show substantial growth in the coming years. As agricultural practices improve and industries like food processing, pharmaceuticals, and cosmetics expand, the demand for starch-based films will continue to rise.
Conclusion
The film forming starches market is poised for significant growth, driven by increasing demand for sustainable, biodegradable alternatives to traditional plastics and other synthetic materials. The production scenario continues to evolve, with manufacturers focusing on enhancing the performance characteristics of starch-based films. Meanwhile, the demand dynamics in global markets reflect a broad spectrum of applications across industries such as food packaging, pharmaceuticals, cosmetics, and agriculture. With innovation and sustainability at the forefront, the film-forming starches market is expected to play a crucial role in meeting the growing need for environmentally friendly materials in the coming years.
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#FilmFormingStarchesMarketEmergingTrends#FilmFormingStarchesMarketRecentInnovations#FilmFormingStarchesMarketProductionScenario#FilmFormingStarchesMarketDemandAnalysis#FilmFormingStarchesMarketGrowthTrends
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Exploring the Key Players in PF Resin Supply Chain: Suppliers, Innovations, and Market Trends
Introduction: Phenol-formaldehyde (PF) resin is a versatile and widely used synthetic resin with applications ranging from wood adhesives to molded products. As industries seek sustainable and high-performance materials, the demand for PF resin continues to grow. Central to meeting this demand are the suppliers who provide the raw materials, expertise, and innovations driving the PF resin market forward. This article delves into the world of PF resin suppliers, exploring their roles, innovations, and the evolving landscape of this essential industry.
The Role of PF Resin Suppliers: PF resin suppliers play a crucial role in the supply chain by providing manufacturers with the raw materials needed to produce Pf Resin Manufacturer in India adhesives, coatings, and other products. These suppliers typically offer a range of PF resin grades tailored to specific applications, including:
Adhesive Grade PF Resins: These resins are formulated to provide strong and durable bonds in wood products, laminates, and composite materials, making them indispensable in the furniture, construction, and automotive industries.
Molding Grade PF Resins: Molding grade PF resins are used in the production of molded products such as electrical components, appliance parts, and decorative items, offering excellent heat resistance and dimensional stability.
Coating Grade PF Resins: PF resins designed for coatings and surface treatments provide protection against moisture, chemicals, and abrasion, making them ideal for applications in marine, aerospace, and industrial sectors.
Innovations in PF Resin Technology: Driven by the demand for sustainable and high-performance materials, PF resin suppliers are continually innovating to improve product quality, environmental sustainability, and application versatility. Key innovations in PF resin technology include:
Low-Formaldehyde Formulations: Suppliers are developing PF resin formulations with reduced formaldehyde emissions to meet stringent regulatory requirements and address consumer preferences for eco-friendly products.
Bio-Based PF Resins: Bio-based PF resins derived from renewable feedstocks such as lignin or agricultural residues offer a sustainable alternative to traditional petroleum-based resins, reducing reliance on fossil fuels and mitigating environmental impact.
Waterborne PF Resins: Waterborne PF resin formulations provide improved safety, handling, and environmental benefits compared to solvent-based resins, contributing to lower VOC emissions and reduced environmental footprint in coating and adhesive applications.
High-Performance Additives: The integration of advanced additives such as crosslinking agents, antioxidants, and UV stabilizers into PF resin formulations enhances product performance, durability, and application versatility in various end-use industries.
Market Trends and Outlook: The PF resin market is characterized by steady growth driven by expanding applications in construction, automotive, electronics, and consumer goods sectors. Key market trends shaping the industry include:
Growing Demand for Engineered Wood Products: The increasing adoption of engineered wood products such as plywood, particleboard, and MDF (medium-density fiberboard) fuels demand for PF resins in wood adhesive applications, particularly in construction and furniture manufacturing.
Shift Towards Sustainable Materials: Consumer preferences for sustainable and environmentally friendly products drive the demand for bio-based and low-formaldehyde PF resin formulations, prompting suppliers to invest in green technologies and product development.
Technological Advancements in Manufacturing: Advances in resin synthesis, process Pf Resin Manufacturer in India optimization, and quality control enable suppliers to enhance product consistency, performance, and cost-effectiveness, driving competitiveness in the global PF resin market.
Conclusion: PF resin suppliers play a critical role in providing the raw materials and innovations that drive the growth and sustainability of industries reliant on synthetic resins. Through ongoing research, development, and collaboration with manufacturers, suppliers continue to push the boundaries of PF resin technology, offering solutions that meet evolving market demands for performance, sustainability, and regulatory compliance. As industries continue to prioritize environmental stewardship and product quality, the role of PF resin suppliers in delivering innovative and sustainable solutions will remain indispensable in shaping the future of materials science and manufacturing.
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Cyanuric Chloride Prices, Trends, and Forecasts - A Comprehensive Analysis
Get the latest insights on price movement and trend analysis of cyanuric chloride in different regions across the world (Asia, Europe, North America, Latin America, and the Middle East & Africa). The chemical industry is continually evolving, and staying up-to-date on market trends and pricing is crucial for both businesses and investors. In this comprehensive blog post, we'll delve into the world of Cyanuric Chloride, exploring its definition, key details, industrial uses, and the major players in the market. By the end, you'll be equipped with the knowledge needed to make informed decisions in this dynamic sector.
Definition of Cyanuric Chloride:
Cyanuric Chloride, also known as 2,4,6-Trichloro-1,3,5-triazine, is a white crystalline chemical compound with the molecular formula C3N3Cl3. It is a chlorinated isocyanuric compound, mainly used in the synthesis of other chemicals. This versatile compound has gained significant importance in various industrial applications due to its unique chemical properties.
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Key Details About Cyanuric Chloride:
Chemical Structure: Cyanuric Chloride is a trichlorinated derivative of cyanuric acid. Its chemical structure consists of a symmetrical hexagonal ring with alternating chlorine atoms attached to carbon and nitrogen atoms. This structure provides the compound with exceptional stability and reactivity.
Physical Properties: Cyanuric Chloride is typically found in the form of white, odorless crystals. It has a melting point of around 145°C (293°F) and is sparingly soluble in water. The compound is stable under normal conditions but should be stored away from heat and incompatible substances.
Chemical Reactions: Cyanuric Chloride is highly reactive, particularly with nucleophiles. It serves as a versatile building block for various chemical reactions, including amidation, acylation, and chlorination. Its reactivity and stability make it a valuable precursor for the synthesis of numerous chemical compounds.
Production Methods: Cyanuric Chloride is primarily produced through the chlorination of cyanuric acid. The process involves the introduction of chlorine gas to cyanuric acid, resulting in the formation of Cyanuric Chloride. The production method and quality control are critical factors influencing the compound's market dynamics.
Industrial Uses Impacting Cyanuric Chloride:
Cyanuric Chloride plays a pivotal role in several industries due to its unique chemical characteristics and versatile applications. Some of the key industrial uses impacting the cyanuric chloride market include:
Pharmaceuticals: Cyanuric Chloride is utilized in pharmaceuticals as a key intermediate in the synthesis of various pharmaceutical compounds, including drugs and active ingredients. Its role in pharmaceutical production has contributed significantly to the growth of the market.
Agrochemicals: The compound finds applications in the production of agrochemicals, including herbicides, pesticides, and fungicides. Its role in enhancing the efficacy and stability of these products is a driving force in the agrochemical industry.
Textile Industry: Cyanuric Chloride is used as a crosslinking agent in the textile industry, aiding in the modification of various textiles and improving their resistance to heat, chemicals, and abrasion. This application has expanded the compound's presence in the textile sector.
Chemical Synthesis: The versatility of Cyanuric Chloride is evident in its role as a reagent for chemical synthesis, especially in the preparation of amines, amides, and other chemical compounds. This application has propelled its demand in the chemical industry.
Water Treatment: In pool and spa water treatment, Cyanuric Chloride is utilized to stabilize chlorine, extending its effectiveness and preventing its degradation due to ultraviolet (UV) radiation. This application is crucial in maintaining safe and clean pool water.
Key Players in the Cyanuric Chloride Market:
To understand the market dynamics of Cyanuric Chloride, it's essential to recognize the key players that contribute significantly to its production and distribution. These companies have a substantial impact on price movements and market trends:
China Petrochemical Corporation (Sinopec): Sinopec is one of the largest chemical producers globally, with a significant presence in the Cyanuric Chloride market. The company's extensive production capabilities and global reach influence market trends and pricing.
Nissan Chemical Corporation: A prominent player in the chemical industry, Nissan Chemical Corporation is known for its high-quality Cyanuric Chloride products. Their commitment to innovation and sustainability has a bearing on market developments.
FMC Corporation: FMC Corporation is a diversified chemical company that produces and markets a range of specialty chemicals, including Cyanuric Chloride. Their global presence and research efforts influence market trends and innovations.
Hebei Jiheng Chemical Co., Ltd.: This Chinese chemical company specializes in the production and distribution of Cyanuric Chloride and its derivatives. Their role in the Asian market is particularly notable.
Occidental Petroleum Corporation: Occidental is a global chemical and petroleum company that plays a significant role in the Cyanuric Chloride market. Their extensive reach and research efforts contribute to the industry's growth.
Trends and Forecasts:
Cyanuric Chloride market trends are influenced by a variety of factors, including raw material prices, regulatory changes, and evolving industry demands. Some key trends and forecasts include:
Increasing Demand in Pharmaceuticals: The pharmaceutical industry's growth is expected to drive increased demand for Cyanuric Chloride as an essential intermediate in drug synthesis.
Sustainable Production Methods: Market players are likely to focus on developing more sustainable production methods to meet environmental regulations and reduce the environmental impact of cyanuric chloride production.
Regional Market Dynamics: Different regions may experience varying market dynamics, influenced by factors like economic development, environmental regulations, and industrial growth.
Technological Advancements: Continuous research and development in the field of chemistry may lead to the discovery of new applications for Cyanuric Chloride, expanding its market potential.
Price Volatility: The prices of Cyanuric Chloride are subject to fluctuations based on factors like supply and demand, production costs, and global economic conditions. Understanding these factors is crucial for market participants.
In conclusion, staying informed about Cyanuric Chloride prices, trends, and forecasts is essential for businesses and investors involved in the chemical industry. As a versatile compound with applications across various sectors, Cyanuric Chloride's market dynamics are influenced by a wide range of factors. By understanding its definition, key details, industrial uses, and the major players in the market, you can make well-informed decisions and navigate the dynamic world of Cyanuric Chloride effectively. Stay tuned for updates on this ever-evolving market.
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Conductive Polymer Coatings Market Size, Share, Demand, Growth & Trends by 2032
The conductive polymer coatings market is projected to grow at an impressive pace with a CAGR of 9.3% during 2022-2032. Widespread use of conductive polymer coatings for corrosion protection and industrial coatings are dominant factors contributing to the market growth.
Increased demand for conductive polymer coatings can be seen in the electrical and electronics industries due to its multipurpose use in computer flat screen displays, personal digital assistants, mobile phones and other screens. These properties are projected to bolster sales in the conductive polymer coatings market.
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Key Takeaways
Its use as an anti-corrosive agent in the electronic engineering field is an ever-growing revenue channel for the conductive polymer coatings market.
The electrical properties such as high electrical conductivity and customization for organic synthesis methods are some of the properties of conductive polymer coatings that are responsible for driving growth in the market.
The major advantage it offers is processability through dispersions. These coatings are made up of some basic polymers such as polyaniline, polypyrene and polyacetylene.
Due to diverse applications of conductive polymer coatings, it has been preferred by every industry. These properties include sensors, optical & electronic materials, actuators, biosensors, super-capacitors, bio-implants and corrosion protection for electrical energy storage.
The drastic replacement of metal and other conductive compounds with conductive polymer coatings from the electrical & electronics industry is expected to drive the market.
With rising disposable income and modernization, demand for electronics has increased tremendously which in turn is expected to drive market growth for conductive polymer coatings.
Asia Pacific region is projected to lead the global conductive polymer coatings market, accounting for a significant market share.
Competitive Landscape
Heraeus
The Lubrizol Corporation
The Dow Chemical Company
Crosslink
ITEK
Henkel Electronics
NanoMarkets LLC.
IDTech EX
Voltaic Coatings
CBI Polymers Inc.
AnCatt
The major international companies in the global conductive polymer coatings market have shifted their manufacturing bases to China for low production costs, and the consumption of these coatings has increased. However, conductive polymer coatings manufacturers are not concentrated in this region.
Insights on the market contribution of various segments, including country- and region-wise historic data and forecast market size (2022 to 2032) – Browse full report: https://www.futuremarketinsights.com/reports/global-conductive-polymer-coatings-market
More Insights into the Conductive Polymer Coatings Market
The Asia Pacific region is predicted to dominate the global conductive polymer coatings market during the forecast years at an unprecedented rate.
Owing to the rising demand for electronics products and reduced production costs, leading manufacturers are shifting their bases in China accounting for global market share.
In terms of consumption, the North American region gains maximum traction over the projected years. Owing to demand from optical and electrical applications conductive polymer coatings market is expected to show a moderate growth rate.
The European region is anticipated to attract the highest growth rate in comparison to other regions during the forecast years owing to the surging demands for conductive polymer coatings.
Fast-paced research and development activities combined with technological advancements in the field of nano-chemistry and optical chemistry are expected to provide opportunities for the players in this market.
Conductive Polymer Coatings Market Key Segments
By Application
Sensors
Fuel Cells
Cell phone
Displays
Touch panel
Solid State Lighting
Displays
Capacitors
Batteries
Photovoltaic Cells
By End-use Industry
Solar industry
Automotive & Locomotive Industry
Electrical & Electronics industries
Smart textiles
By Region
North America
Latin America
Asia Pacific
Japan
Western Europe
Eastern Europe
Middle East & Africa
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50% Discount - Crosslinking Agent: Market Report of China 2018-2027
50% Discount – Crosslinking Agent: Market Report of China 2018-2027
Market Reports on China Provides the Trending Market Research Report on “Crosslinking Agent Industry Forecasts – China Focus” under Chemical & Materials category. The report offers a collection of china market Trends, china market analysis, cihna business trends and china market size and growth.
This study focuses on China’s Crosslinking Agent industryforecasts. In the two past decades, the…
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Phenyl Chlorosilane Market Growth, Size, Analysis, Outlook by Trends, Opportunities and Forecast to 2028
Phenyl chlorosilane is used as a raw material for silicone oil and silicone resin, and is also used in the paint industry.
Based on the Phenyl Chlorosilane market development status, competitive landscape and development model in different regions of the world, this report is dedicated to providing niche markets, potential risks and comprehensive competitive strategy analysis in different fields. From the competitive advantages of different types of products and services, the development opportunities and consumption characteristics and structure analysis of the downstream application fields are all analyzed in detail. To Boost Growth during the epidemic era, this report analyzes in detail for the potential risks and opportunities which can be focused on.
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Key players in the global Phenyl Chlorosilane market covered :
Shin-Etsu Chemical Co., Ltd. Elkem Silibase Silicone Momentive Evonik Silar Dow Corning
the basis of types, the Phenyl Chlorosilane market from 2015 to 2025 is primarily split into:
> 95 % > 98 % 99 %
the basis of applications, the Phenyl Chlorosilane market from 2015 to 2025 covers:
Adhesion Promoter Catalyst Coupling Agent Crosslinking Agent Curing Agent Dispersing Agent Hydrophobic additive Hydrophobic surface treatment Moisture Scavenger Organosilicone intermediate Polyurethane Endcapper Reinforcer Silyl Building Blocks and Synthons Silylating Agent Thermal Stabilizer
Geographically, the detailed analysis of consumption, revenue, market share and growth rate, historic and forecast :
North America
United States
Canada
Mexico
Europe
Germany
UK
France
Italy
Spain
Russia
Others
Asia-Pacific
China
Japan
South Korea
Australia
India
South America
Brazil
Argentina
Columbia
Middle East and Africa
UAE
Egypt
South Africa
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Table of Content
1 Market Overview
1.1 Product Definition and Market Characteristics
1.2 Global Phenyl Chlorosilane Market Size
1.3 Market Segmentation
1.4 Global Macroeconomic Analysis
1.5 SWOT Analysis
2. Market Dynamics
2.1 Market Drivers
2.2 Market Constraints and Challenges
2.3 Emerging Market Trends
2.4 Impact of COVID-19
2.4.1 Short-term Impact
2.4.2 Long-term Impact
3 Associated Industry Assessment
3.1 Supply Chain Analysis
3.2 Industry Active Participants
3.2.1 Suppliers of Raw Materials
3.2.2 Key Distributors/Retailers
3.3 Alternative Analysis
3.4 The Impact of Covid-19 From the Perspective of Industry Chain
4 Market Competitive Landscape
4.1 Industry Leading Players
4.2 Industry News
4.2.1 Key Product Launch News
4.2.2 M&A and Expansion Plans
5 Analysis of Leading Companies
5.1 Shin-Etsu Chemical Co., Ltd. 5.1.1 Shin-Etsu Chemical Co., Ltd. Company Profile 5.1.2 Shin-Etsu Chemical Co., Ltd. Business Overview 5.1.3 Shin-Etsu Chemical Co., Ltd. Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.1.4 Shin-Etsu Chemical Co., Ltd. Phenyl Chlorosilane Products Introduction 5.2 Elkem 5.2.1 Elkem Company Profile 5.2.2 Elkem Business Overview 5.2.3 Elkem Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.2.4 Elkem Phenyl Chlorosilane Products Introduction 5.3 Silibase Silicone 5.3.1 Silibase Silicone Company Profile 5.3.2 Silibase Silicone Business Overview 5.3.3 Silibase Silicone Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.3.4 Silibase Silicone Phenyl Chlorosilane Products Introduction 5.4 Momentive 5.4.1 Momentive Company Profile 5.4.2 Momentive Business Overview 5.4.3 Momentive Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.4.4 Momentive Phenyl Chlorosilane Products Introduction 5.5 Evonik 5.5.1 Evonik Company Profile 5.5.2 Evonik Business Overview 5.5.3 Evonik Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.5.4 Evonik Phenyl Chlorosilane Products Introduction 5.6 Silar 5.6.1 Silar Company Profile 5.6.2 Silar Business Overview 5.6.3 Silar Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.6.4 Silar Phenyl Chlorosilane Products Introduction 5.7 Dow Corning 5.7.1 Dow Corning Company Profile 5.7.2 Dow Corning Business Overview 5.7.3 Dow Corning Phenyl Chlorosilane Sales, Revenue, Average Selling Price and Gross Margin (2015-2020) 5.7.4 Dow Corning Phenyl Chlorosilane Products Introduction
6 Market Analysis and Forecast, By Product Types
6.1 Global Phenyl Chlorosilane Sales, Revenue and Market Share by Types (2015-2020)
6.1.1 Global Phenyl Chlorosilane Sales and Market Share by Types (2015-2020)
6.1.2 Global Phenyl Chlorosilane Revenue and Market Share by Types (2015-2020)
6.1.3 Global Phenyl Chlorosilane Price by Types (2015-2020)
6.2 Global Phenyl Chlorosilane Market Forecast by Types (2020-2025)
6.2.1 Global Phenyl Chlorosilane Market Forecast Sales and Market Share by Types (2020-2025)
6.2.2 Global Phenyl Chlorosilane Market Forecast Revenue and Market Share by Types (2020-2025)
6.3 Global Phenyl Chlorosilane Sales, Price and Growth Rate by Types (2015-2020)
6.3.1 Global Phenyl Chlorosilane Sales, Price and Growth Rate of > 95 % 6.3.2 Global Phenyl Chlorosilane Sales, Price and Growth Rate of > 98 % 6.3.3 Global Phenyl Chlorosilane Sales, Price and Growth Rate of 99 % 6.4 Global Phenyl Chlorosilane Market Revenue and Sales Forecast, by Types (2020-2025)
6.4.1 > 95 % Market Revenue and Sales Forecast (2020-2025) 6.4.2 > 98 % Market Revenue and Sales Forecast (2020-2025) 6.4.3 99 % Market Revenue and Sales Forecast (2020-2025)
7 Market Analysis and Forecast, By Applications
7.1 Global Phenyl Chlorosilane Sales, Revenue and Market Share by Applications (2015-2020)
7.1.1 Global Phenyl Chlorosilane Sales and Market Share by Applications (2015-2020)
7.1.2 Global Phenyl Chlorosilane Revenue and Market Share by Applications (2015-2020)
7.2 Global Phenyl Chlorosilane Market Forecast by Applications (2020-2025)
7.2.1 Global Phenyl Chlorosilane Market Forecast Sales and Market Share by Applications (2020-2025)
7.2.2 Global Phenyl Chlorosilane Market Forecast Revenue and Market Share by Applications (2020-2025)
7.3 Global Revenue, Sales and Growth Rate by Applications (2015-2020)
7.3.1 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Adhesion Promoter (2015-2020) 7.3.2 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Catalyst (2015-2020) 7.3.3 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Coupling Agent (2015-2020) 7.3.4 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Crosslinking Agent (2015-2020) 7.3.5 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Curing Agent (2015-2020) 7.3.6 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Dispersing Agent (2015-2020) 7.3.7 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Hydrophobic additive (2015-2020) 7.3.8 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Hydrophobic surface treatment (2015-2020) 7.3.9 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Moisture Scavenger (2015-2020) 7.3.10 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Organosilicone intermediate (2015-2020) 7.3.11 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Polyurethane Endcapper (2015-2020) 7.3.12 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Reinforcer (2015-2020) 7.3.13 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Silyl Building Blocks and Synthons (2015-2020) 7.3.14 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Silylating Agent (2015-2020) 7.3.15 Global Phenyl Chlorosilane Revenue, Sales and Growth Rate of Thermal Stabilizer (2015-2020) 7.4 Global Phenyl Chlorosilane Market Revenue and Sales Forecast, by Applications (2020-2025)
7.4.1 Adhesion Promoter Market Revenue and Sales Forecast (2020-2025) 7.4.2 Catalyst Market Revenue and Sales Forecast (2020-2025) 7.4.3 Coupling Agent Market Revenue and Sales Forecast (2020-2025) 7.4.4 Crosslinking Agent Market Revenue and Sales Forecast (2020-2025) 7.4.5 Curing Agent Market Revenue and Sales Forecast (2020-2025) 7.4.6 Dispersing Agent Market Revenue and Sales Forecast (2020-2025) 7.4.7 Hydrophobic additive Market Revenue and Sales Forecast (2020-2025) 7.4.8 Hydrophobic surface treatment Market Revenue and Sales Forecast (2020-2025) 7.4.9 Moisture Scavenger Market Revenue and Sales Forecast (2020-2025) 7.4.10 Organosilicone intermediate Market Revenue and Sales Forecast (2020-2025) 7.4.11 Polyurethane Endcapper Market Revenue and Sales Forecast (2020-2025) 7.4.12 Reinforcer Market Revenue and Sales Forecast (2020-2025) 7.4.13 Silyl Building Blocks and Synthons Market Revenue and Sales Forecast (2020-2025) 7.4.14 Silylating Agent Market Revenue and Sales Forecast (2020-2025) 7.4.15 Thermal Stabilizer Market Revenue and Sales Forecast (2020-2025)
8 Market Analysis and Forecast, By Regions
8.1 Global Phenyl Chlorosilane Sales by Regions (2015-2020)
8.2 Global Phenyl Chlorosilane Market Revenue by Regions (2015-2020)
8.3 Global Phenyl Chlorosilane Market Forecast by Regions (2020-2025)
9 North America Phenyl Chlorosilane Market Analysis
9.1 Market Overview and Prospect Analysis
9.2 North America Phenyl Chlorosilane Market Sales and Growth Rate (2015-2020)
9.3 North America Phenyl Chlorosilane Market Revenue and Growth Rate (2015-2020)
9.4 North America Phenyl Chlorosilane Market Forecast
9.5 The Influence of COVID-19 on North America Market
9.6 North America Phenyl Chlorosilane Market Analysis by Country
9.6.1 U.S. Phenyl Chlorosilane Sales and Growth Rate
9.6.2 Canada Phenyl Chlorosilane Sales and Growth Rate
9.6.3 Mexico Phenyl Chlorosilane Sales and Growth Rate
10 Europe Phenyl Chlorosilane Market Analysis
10.1 Market Overview and Prospect Analysis
10.2 Europe Phenyl Chlorosilane Market Sales and Growth Rate (2015-2020)
10.3 Europe Phenyl Chlorosilane Market Revenue and Growth Rate (2015-2020)
10.4 Europe Phenyl Chlorosilane Market Forecast
10.5 The Influence of COVID-19 on Europe Market
10.6 Europe Phenyl Chlorosilane Market Analysis by Country
10.6.1 Germany Phenyl Chlorosilane Sales and Growth Rate
10.6.2 United Kingdom Phenyl Chlorosilane Sales and Growth Rate
10.6.3 France Phenyl Chlorosilane Sales and Growth Rate
10.6.4 Italy Phenyl Chlorosilane Sales and Growth Rate
10.6.5 Spain Phenyl Chlorosilane Sales and Growth Rate
10.6.6 Russia Phenyl Chlorosilane Sales and Growth Rate
11 Asia-Pacific Phenyl Chlorosilane Market Analysis
11.1 Market Overview and Prospect Analysis
11.2 Asia-Pacific Phenyl Chlorosilane Market Sales and Growth Rate (2015-2020)
11.3 Asia-Pacific Phenyl Chlorosilane Market Revenue and Growth Rate (2015-2020)
11.4 Asia-Pacific Phenyl Chlorosilane Market Forecast
11.5 The Influence of COVID-19 on Asia Pacific Market
11.6 Asia-Pacific Phenyl Chlorosilane Market Analysis by Country
11.6.1 China Phenyl Chlorosilane Sales and Growth Rate
11.6.2 Japan Phenyl Chlorosilane Sales and Growth Rate
11.6.3 South Korea Phenyl Chlorosilane Sales and Growth Rate
11.6.4 Australia Phenyl Chlorosilane Sales and Growth Rate
11.6.5 India Phenyl Chlorosilane Sales and Growth Rate
12 South America Phenyl Chlorosilane Market Analysis
12.1 Market Overview and Prospect Analysis
12.2 South America Phenyl Chlorosilane Market Sales and Growth Rate (2015-2020)
12.3 South America Phenyl Chlorosilane Market Revenue and Growth Rate (2015-2020)
12.4 South America Phenyl Chlorosilane Market Forecast
12.5 The Influence of COVID-19 on South America Market
12.6 South America Phenyl Chlorosilane Market Analysis by Country
12.6.1 Brazil Phenyl Chlorosilane Sales and Growth Rate
12.6.2 Argentina Phenyl Chlorosilane Sales and Growth Rate
12.6.3 Columbia Phenyl Chlorosilane Sales and Growth Rate
13 Middle East and Africa Phenyl Chlorosilane Market Analysis
13.1 Market Overview and Prospect Analysis
13.2 Middle East and Africa Phenyl Chlorosilane Market Sales and Growth Rate (2015-2020)
13.3 Middle East and Africa Phenyl Chlorosilane Market Revenue and Growth Rate (2015-2020)
13.4 Middle East and Africa Phenyl Chlorosilane Market Forecast
13.5 The Influence of COVID-19 on Middle East and Africa Market
13.6 Middle East and Africa Phenyl Chlorosilane Market Analysis by Country
13.6.1 UAE Phenyl Chlorosilane Sales and Growth Rate
13.6.2 Egypt Phenyl Chlorosilane Sales and Growth Rate
13.6.3 South Africa Phenyl Chlorosilane Sales and Growth Rate
14 Conclusions and Recommendations
14.1 Key Market Findings and Prospects
14.2 Advice for Investors
15 Appendix
15.1 Methodology
15.2 Research Data Source
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Polyelectrolyte Market | Exclusive Report on the Latest Trends and Opportunities in the Market
Global Polyelectrolyte Market: Overview
End-use industries have been leveraging an array of physicochemical characteristics of polyelectrolyte—a special category of polymer—in numerous applications. Apparently, their use as flocculation agents, dispersants, and super-plasticizers has proliferated over the years.
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Additionally, they have been used as emulsifier and conditioner for manufacturing consumer products especially cosmetics. Advances in material sciences have expanded the repository of products that utilize the physical and chemical properties of polyelectrolytes.
Key applications might comprise wastewater treatment, medical, food manufacturing, and in making wide range of personal care products notably hygiene products. A few important class of applications stems from creating crosslinking in polyelectrolytes. A notable case in point is super absorbents (SAPs) or hydrogels.
Industries in the pursuit of developing smart materials find polyelectrolyte and their complexes as an attractive candidate. Trends that may impact their return on investments in the polyelectrolyte market find in-depth discussions in this report. Strategies that will set the pace of new demand dynamics are closely scrutinized in the research.
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Global Polyelectrolyte Market: Notable Developments
Growing body of research in material sciences has led to the advent of new product types with novel properties in the polyelectrolyte market.
Polyelectrolyte multilayer films (PEMs) have grown in commercial significance in the polyelectrolyte market over the recent decade. A case in point is industry efforts in harnessing the properties of PEMs in antimicrobial coatings for medical implants.
Recent years have seen industry players in the polyelectrolytes market unveiling new types of PEMs they hit upon by trying new, novel approaches. A recent study published in August 2018 revealed how a team of researchers leveraged block copolymer (BCP) approach to develop polyelectrolyte multilayer-like films. They accomplished this by layer-by-layer deposition of alternating polyanion and polycation solutions. The authors are affiliated with The Dow Chemical Company, a well-entrenched player in the polyelectrolyte market.
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Relentless pursuit of finding new materials for nanotechnology has laid bare new categories of products in the polyelectrolyte market. In recent years, the use of polyelectrolyte brushes has gathered some steam. They hold enormous promise in providing lubrication between the surfaces of engineered as well as physiological materials. Recent research has been harnessing this potential in developing cutting-edge biomedical devices.
Global Polyelectrolyte Market: Growth Drivers
Recent body of research and development initiatives in materials sciences have been successful in unlocking novel materials for commercial applications. A promising case in point is harnessing the biochemical properties of polyelectrolyte complexes for manufacturing medical devices, such as implant coatings, and in therapeutics notably controlled drug release systems.
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Further, new streams of revenue emanate from the potential use of polyelectrolyte complexes for nanoarchitectonics. An example is growing utilization of polyelectrolyte complexes in nanocomposite coatings that can be used in specialized corrosion protection.
Over the past few years, both natural and synthetic polyelectrolytes have been utilized at rapid pace by end-use industries, imparting noticeable momentum to the polyelectrolyte market. Polyelectrolytes manufacturers in recent years are developing products that cater to wide cross-section of needs in industries. A case in point is the rising application in the food production. Particularly, they are witnessing substantial use in food coatings and release agents of natural origin. Rising consumption of super absorbents (SAPs) in the personal care industry, notably baby care products, in developing economies has been contributing to the expansion of the polyelectrolyte market.
Another application area that might serve as a source of sizable revenues to the polyelectrolyte market is smart drug delivery. To this end, multilayer nanofilms are an increasingly promising candidate. Strides being made in nanotechnology are expediting the pace of developments in this direction.
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Zinc Acetylacetonate Market Report | Global Forecast To 2028
The global zinc acetylacetonate market is expected to grow at a CAGR of 3.5% during the forecast period, to reach USD 1.2 billion by 2028. The growth of this market is driven by the increasing demand for PVC stabilizers and croslinking agents in various industries such as construction, automotive, and packaging. The increasing demand for PVC stabilizers and croslinking agents in various industries such as construction, automotive, and packaging is driving the growth of this market.
The global zinc acetylacetonate market has been segmented on the basis of type (more than or equal to 98%), application (PVC stabilizer, crosslinking agent, former agent), and region (North America, Latin America, Europe Asia Pacific Middle East & Africa). North America accounted for a major share in terms of revenue generation due to its high consumption rate in various applications such as PVC stabilizer and crosslinking agent. Europe accounted for a major share in terms of revenue generation due to its high consumption rate in various applications such as PVC stabilizer and crosslinking agent. Asia Pacific accounted for a major share in terms of revenue generation due to its high consumption rate in various applications such as PVC stabilizer and crosslinking agent.
Some Of The Growth Factors Of This Market:
Zinc Acetylacetonate is used in the production of polymers, paints, and rubber products.
The demand for zinc acetylacetonate is expected to increase due to its use in the production of polymers, paints, and rubber products.
Zinc acetylacetonate is a white crystalline powder with a melting point of about 130 degrees Celsius and a boiling point of about 300 degrees Celsius.
Zinc acetylacetonate has been found to be an effective catalyst for polymerization reactions such as those that produce polyurethanes and epoxy resins which are used in coatings for cars or boats or other industrial applications where durability is important; it also has been found to be an effective catalyst for polymerization reactions such as those that produce polyesters which are used in clothing fabrics or carpets; it also has been found to be an effective catalyst for polymerization reactions such as those that produce styrene-butadiene rubber which is used in tires or footwear soles; it also has been found to be an effective catalyst for polymerization reactions such as those that produce acrylics which are used in paints or adhesives; it also has been found to be an effective catalyst for polymerization reactions such as those that produce vinyl chloride monomer (VCM) which is used in PVC plastics like pipes, films, sheets, bottles etc;.
The global market size of zinc acetylacetonate was estimated at USD 1 billion by 2017 end with China being the largest producer followed by India.
Industry Growth Insights published a new data on “Zinc Acetylacetonate Market”. The research report is titled “Zinc Acetylacetonate Market research by Types (More than or euqal to98%, Others), By Applications (PVC Stabilizer, Cross-linking Agent, Former Agent, Catalyst & Additive, Others), By Players/Companies Multi-tech (Tianjin) Specialty Chemicals, Nanjing Lanya Chemical, SACHEM, Inc., Triad Chemical, Inc., Huzhou Xinaote Pharmaceutical & Chemical, Amspec Chemical Corporation, Nihon Kagaku Sangyo Co., Ltd., Lorad Chemical Corporation, Liaocheng JunHang Biotech, Yangzhou Xingye Additives, Huzhou City Linghu Xinwang Chemical, Nanjing Lepuz Chemical, Chongqing Furun Chemicals”.
Detailed Report: https://industrygrowthinsights.com/report/zinc-acetylacetonate-market/
Global Zinc Acetylacetonate Market Report Segments:
The global Zinc Acetylacetonate market is segmented on the basis of:
Types
More than or euqal to98%, Others
The product segment provides information about the market share of each product and the respective CAGR during the forecast period. It lays out information about the product pricing parameters, trends, and profits that provides in-depth insights of the market. Furthermore, it discusses latest product developments & innovation in the market.
Applications
PVC Stabilizer, Cross-linking Agent, Former Agent, Catalyst & Additive, Others
The application segment fragments various applications of the product and provides information on the market share and growth rate of each application segment. It discusses the potential future applications of the products and driving and restraining factors of each application segment.
Some of the companies that are profiled in this report are:
Multi-tech (Tianjin) Specialty Chemicals
Nanjing Lanya Chemical
SACHEM, Inc.
Triad Chemical, Inc.
Huzhou Xinaote Pharmaceutical & Chemical
Amspec Chemical Corporation
Nihon Kagaku Sangyo Co., Ltd.
Lorad Chemical Corporation
Liaocheng JunHang Biotech
Yangzhou Xingye Additives
Huzhou City Linghu Xinwang Chemical
Nanjing Lepuz Chemical
Chongqing Furun Chemicals
Highlights of The Zinc Acetylacetonate Market Report:
The market structure and projections for the coming years.
Drivers, restraints, opportunities, and current trends of Alpha Hydroxy Acid for Cosmetic Market.
Historical data and forecast.
Estimations for the forecast period 2028.
Developments and trends in the market.
By Type:
More than or euqal to98%
Others
By Application:
PVC Stabilizer
Cross-linking Agent
Former Agent
Catalyst & Additive
Others
Market scenario by region, sub-region, and country.
Market share of the market players, company profiles, product specifications, SWOT analysis, and competitive landscape.
Analysis regarding upstream raw materials, downstream demand, and current market dynamics.
Government Policies, Macro & Micro economic factors are also included in the report.
We have studied the Zinc Acetylacetonate Market in 360 degrees via. both primary & secondary research methodologies. This helped us in building an understanding of the current market dynamics, supply-demand gap, pricing trends, product preferences, consumer patterns & so on. The findings were further validated through primary research with industry experts & opinion leaders across countries. The data is further compiled & validated through various market estimation & data validation methodologies. Further, we also have our in-house data forecasting model to predict market growth up to 2028.
Regional Analysis
North America
Europe
Asia Pacific
Middle East & Africa
Latin America
Note: A country of choice can be added in the report at no extra cost. If more than one country needs to be added, the research quote will vary accordingly.
The geographical analysis part of the report provides information about the product sales in terms of volume and revenue in regions. It lays out potential opportunities for the new entrants, emerging players, and major players in the region. The regional analysis is done after considering the socio-economic factors and government regulations of the countries in the regions.
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Includes a Chapter on the Impact of COVID-19 Pandemic On the Market
Report Prepared After Conducting Interviews with Industry Experts & Top Designates of the Companies in the Market
Implemented Robust Methodology to Prepare the Report
Includes Graphs, Statistics, Flowcharts, and Infographics to Save Time
Industry Growth Insights Provides 24/5 Assistance Regarding the Doubts in the Report
Provides Information About the Top-winning Strategies Implemented by Industry Players.
In-depth Insights On the Market Drivers, Restraints, Opportunities, and Threats
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Phenyl Chlorosilane Market 2021 | Covid19 Impact Analysis | Size, Share, Sales and Forecast to 2026: Silibase Silicone, Silar, Shin-Etsu Chemical Co., Ltd., Evonik, etc.
Global Phenyl Chlorosilane Market 2021 report is comprised of an in-depth analysis of the global industry which aims to deliver comprehensive market intelligence study associated with major market components. The report includes an overview of these markets on different fronts such as market size, market share, market penetration of the product and services, market downstream fields, key vendors operating within the territory, market price analysis and more. This might help readers across the worldwide business industry to comprehend a lot about the regional as well as key domestic markets for Phenyl Chlorosilane. Reports include an overview and examination of the major companies operating within the industry which are considered to be revenue drivers for the market.
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Top Key players of Phenyl Chlorosilane Market Covered In The Report: Silibase Silicone Silar Shin-Etsu Chemical Co., Ltd. Evonik Momentive Dow Corning Elkem Key Market Segmentation of Phenyl Chlorosilane:
on the basis of types, the Phenyl Chlorosilane market from 2015 to 2025 is primarily split into:
> 95 % > 98 % 99 % on the basis of applications, the Phenyl Chlorosilane market from 2015 to 2025 covers:
Adhesion Promoter Catalyst Coupling Agent Crosslinking Agent Curing Agent Dispersing Agent Hydrophobic additive Hydrophobic surface treatment Moisture Scavenger Organosilicone intermediate Polyurethane Endcapper Reinforcer Silyl Building Blocks and Synthons Silylating Agent Thermal Stabilizer
The Phenyl Chlorosilane report includes the study of these ventures on parameters such as market share, company profile, revenue figures, sales data, market presence, product or service portfolio, past performance, expected performance, and more. This may assist those who are willing to enhance their know-how of the competitive scenario of the Phenyl Chlorosilane Market.
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Key Highlights from Phenyl Chlorosilane Market Study:
Income and Sales Estimation – Historical Revenue and deals volume is displayed and supports information is triangulated with best down and base up ways to deal with figure finish market measure and to estimate conjecture numbers for key areas shrouded in the Phenyl Chlorosilane report alongside arranged and very much perceived Types and end-utilize industry. Moreover, macroeconomic factors and administrative procedures are discovered explanation in Phenyl Chlorosilane industry advancement and perceptive examination.
Assembling Analysis – The Phenyl Chlorosilane report is presently broken down concerning different types and applications. The Phenyl Chlorosilane market gives a section featuring the assembling procedure examination approved by means of essential data gathered through Industry specialists and Key authorities of profiled organizations.
Competition Analysis – Phenyl Chlorosilane Leading players have been considered relying upon their organization profile, item portfolio, limit, item/benefit value, deals, and cost/benefit.
Demand and Supply and Effectiveness –
Phenyl Chlorosilane report moreover gives support, Production, Consumption and (Export and Import).
Phenyl Chlorosilane Market Region Mainly Focusing: — Europe Phenyl Chlorosilane Market (Austria, France, Finland, Switzerland, Italy, Germany, Netherlands, Poland, Russia, Spain, Sweden, Turkey, UK), — Asia-Pacific and Australia Phenyl Chlorosilane Market (China, South Korea, Thailand, India, Vietnam, Malaysia, Indonesia, and Japan), — The Middle East and Africa Phenyl Chlorosilane Market (Saudi Arabia, South Africa, Egypt, Morocco, and Nigeria), — Latin America/South America Phenyl Chlorosilane Market (Brazil and Argentina), — North America Phenyl Chlorosilane Market (Canada, Mexico, and The USA)
The Phenyl Chlorosilane Market report concludes with sharing vital report findings with readers. Here on the basis of study of historical data, examination of the current scenarios overserved in various markets including regional and domestic and trends recorded, it delivers forecast of the market. This includes segmental forecast, regional market forecast, market size forecast, consumption forecast.
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Phenyl Chlorosilane, Phenyl Chlorosilane Market, COVID19 Impact on Phenyl Chlorosilane Market, Phenyl Chlorosilane Forecast, Phenyl Chlorosilane Market Growth, Phenyl Chlorosilane Market Sales, Phenyl Chlorosilane Market Size, Phenyl Chlorosilane Market Regional Analysis
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Global Medical Grade Hydrogel Market Research Report 2021 | Teikoku Pharma,Hisamitsu
Global Info Research offers an overarching research and analysis-based study on, “Global Medical Grade Hydrogel Market 2021 by Manufacturers, Regions, Type and Application, Forecast to 2026”. The Medical Grade Hydrogel market report provides a detailed analysis of global market size, regional and country-level market size, segmentation market growth, market share, competitive Landscape, sales analysis, impact of domestic and global market players, value chain optimization, trade regulations, recent developments, opportunities analysis, strategic market growth analysis, product launches, area marketplace expanding, and technological innovations.
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According to our latest research, the global Medical Grade Hydrogel size is estimated to be XX million in 2021 from USD 2269.9 million in 2020, with a change of XX% between 2020 and 2021. The global Medical Grade Hydrogel market size is expected to grow at a CAGR of 2.5% for the next five years.
Market Segment by Product Type:
Physical Crosslinked Hydrogels
Crosslinking Agent Crosslinked Hydrogels
Market Segment by Application:
Hydrogel Dressing
Drug Delivery Systems (DDS)
Implants
Others
Top Companies/Manufacturers:
Teikoku Pharma
Hisamitsu
Johnson & Johnson
Novartis
ConvaTec
Smith&Nephew United
Hollister
Paul Hartmann
Coloplast
3M
Molnlycke Health Care
Axelgaard
Jiyuan
Guojia
Huayang
The content of this report includes 14 chapters:
Chapter 1, to describe Medical Grade Hydrogel product scope, market overview, market opportunities, market driving force and market risks.
Chapter 2, to profile the top manufacturers of Medical Grade Hydrogel, with price, sales, revenue and global market share of Medical Grade Hydrogel from 2019 to 2021.
Chapter 3, the Medical Grade Hydrogel competitive situation, sales, revenue and global market share of top manufacturers are analyzed emphatically by landscape contrast.
Chapter 4, the Medical Grade Hydrogel breakdown data are shown at the regional level, to show the sales, revenue and growth by regions, from 2016 to 2026.
Chapter 5 and 6, to segment the sales by type and application, with sales market share and growth rate by type, application, from 2016 to 2026.
Chapter 7, 8, 9, 10 and 11, to break the sales data at the country level, with sales, revenue and market share for key countries in the world, from 2016 to 2021.and Medical Grade Hydrogel market forecast, by regions, type and application, with sales and revenue, from 2021 to 2026.
Chapter 12, 13 and 14, to describe Medical Grade Hydrogel sales channel, distributors, customers, research findings and conclusion, appendix and data source.
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SWOT analysis of competitors, cost and profit analysis and potential industry turnover analysis
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The crosslinking agents, due to their application of heat resistance paints, high performance and floor coating will accelerate the growth of the market. Increasing usage of water based coatings will impact positively by increasing the demand in the market. The growth of the powder coating application will help to surge the market growth of crosslinking agent
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Plastic Coatings Market – Size ,Market Drivers, Restraints, Potential Growth Opportunities Market Insights, Trends Sales, Supply, Demand 2019-2027
Plastic Coating Market Industry/ Innovation/ Related News:
November 23, 2017– DSM invests USD 18.12 million to expand capacity at Coating Resins plant in Meppen (Germany).DSM is a global science company active in health, nutrition and materials, announced it has invested USD 15 18.12 million for the expansion of its Coating Resins plant in Meppen, Germany. The facility is specialized in the production of liquid polyesters and other specialty resins. With this expansion, DSM Coating Resins reinforces its position in the can and coil coatings segment and ensures it remains fit for growth in the BPA-free market. The investment will enable greater supply flexibility, the ability to meet growing demand and improved stock management. The overall impact of this investment to be seen in coatings especially in plastic application and likely to drive its demand in automotive applications.
August 17, 2017- Axalta Coating Systems completes the acquisition of Plascoat Systems Limited. a leading supplier of thermoplastic powder coatings, from its parent company, International Process Technologies (IPT) Ltd. Financial terms of the transaction were not disclosed. With this acquisition, production of dicumyl peroxide (DCP), an organic peroxide used as a crosslinking agent in the manufacture of polymers is increased by 40% at 38000 tons per years.
Jun 20, 2017 – One of the leading chemical industry player, BASF invests USD 40 million in automotive coatings in North America. The company expanding their automotive coatings production in North America with investments of nearly USD 40 million, this investment will adds capacity to the company’s production plants in Tultitlan and Mexico. Although the investment has made in automate paints, the overall impact of this investment expected to be seen in Plastic coatings as well. This is due to, Plastic coatings accounts for the substantial shares in overall automotive paints & coating application and this aforementioned investment could be the game changes in this market.
May 24, 2017 – The Dow Chemical Company announced to expand Plastic and coatings capacity in Saudi Arabia. As a part of their strategic expansion the company has signed agreement to construct a state-of-the-art manufacturing facility to produce a range of polymers for coatings. Moreover, Dow has been a long-term strategic partner in Saudi Arabia for nearly four decades and is the largest foreign investor in the country. This could be the added advantage for them and this may help them to strengthen their market position. The proposed Plastics investment will include constructing a fully-integrated slogans and high performance Plastics coating market size complex geared towards markets and industries such as home and personal care, automotive, high performance building and construction, solar energy, medical devices, and oil and gas.
January 1, 2017- Shin-Etsu Chemical announces to expand Plastics production capacity in the U.S. the company recently announced plans to expand the production capacity of its Akron, Ohio plant, Shin-Etsu Plastics of America (SESA), which is engaged in the manufacturing and sales of Plastics. The amount of this facility investment is USD 1.4 billion, and the expansion work is aimed for completion in the middle of 2019. As per the industry experts, the overall impact of this investment expected to drive the demand for Plastic coatings in the coming years.
Competitive Landscape
The report analyses the degree of competition among the industry players as well as industry growth and market scenario. Industry competition among the key market participants is observed as moderate to high. With consistent rise in demand for plastic coatings and increasing pressure from governmental bodies to reduce environmental impact, key industry participants are focusing on new product innovation. Some of the investment are also seen in the researches and development to innovate new product formulation, therefore, the overall industry competition is expected to rise in the coming years.
Bayer AG, 3M Company, BASF SE, PPG Industries Inc., Eastman Chemical Company, Akzo Nobel N.V., Wacker Chemie AG, Kansai Paints Co Ltd., Axalta Coating Systems, and Valspar Corporation. among others are some of the prominent players at the forefront of competition in the Global Plastic Coatings Market and are profiled in MRFR Analysis.
Plastic Coatings Market – Overview
Plastic coating exhibits functional uses including corrosion inhibition, abrasion resistance, thermal resistance, chemical resistance, UV resistance, lubrication, mechanical property enhancement, surface finish, and esthetics. Moreover, overall application scope of plastic coatings covers automotive, oil & gas, building & construction, electronics, aerospace and defense. Among all automotive, building & construction and aerospace & defense are the major consumer of the plastic castings and are consistently providing the growth offerings. Over the past few years the global plastic coating market has been experiencing prolific demand and it is expected to grow significantly over the assessment period. Growth in this market is highly attributed to the plastic coatings are widely used in automobile industry for coating the battery trays, seat springs radiator grilles, brackets, door handles, filler pipes, and seat belt loops. In addition to this, increasing automotive production likely to provide healthy growth opportunities for key industry participants in this coming years. Although driven by aforementioned factors, the global demand for plastic coatings is inhibited by the huge impact on the environment due to VOC emissions.
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NOTE: Our Team of Researchers are Studying Covid19 and its Impact on Various Industry Verticals and wherever required we will be considering Covid19 Footprints for Better Analysis of Market and Industries. Cordially get in Touch for More Details.
#Plastic Coating Market#Global Plastic Coating Market#Plastic Coating Industry#Plastic Coating Market Share
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Lupine Publishers | Advances in Antibacterial Textile Sutures
Lupine Publishers | Trends in Ophthalmology open Access Journal
Abstract
The article highlights some significant research trends in the development in antibacterial textile sutures. Braided polyamide sutures are frequently used in dermatologic surgery for wound closure. However, braided sutures promote bacteria proliferation. In order to prevent wound complications due to this effect, antibacterial sutures should be used. The major focus has been the development of new non-absorbable antibacterial polyamide braided suture. A new coating process has been proposed that leads to obtain suture uniformly covered by antibacterial film enclosing chitosan, which is known for its antibacterial benefit. Silk sutures have been treated with natural fungal pigment in varying concentrations. Also, the influence on the silk suture properties like tenacity, knot strength, friction and antimicrobial activity has been studied. Attempts have been made to systematically study the randomized, controlled trials that compare the use of antibacterial sutures (ABS) for skin closure in controlling surgical site infections.
Keywords: Braided Polyamide Suture; Antibacterial Effect; Chitosan; Wound Closure; Pigment; Fungal
Introduction
Today sutures are the most implanted biomaterials in human body because they are used in almost all wound closure [1]. They are either multifilaments (twisted or braided) or monofilament [2]. They have physical and chemical properties quite different from each other. In the last century, synthetic materials, both absorbable and non-absorbable, have been introduced in the making of surgical sutures. Wound closure using suture materials is an integral part of the surgical process. Sutures are natural or synthetic textile biomaterials widely used in wound closure, to ligate blood vessels and to draw tissues together [3]. Sutures consist of a fibre or fibrous structure with a metallic needle attached at one of the fibre ends and they can be classified into two broad categories namely absorbable and non-absorbable sutures. Surgical site infection (SSI) is an immense burden on healthcare resources even in the modern era of immaculate sterilization approaches and highly effective antibiotics. An estimated 234 million various surgical procedures, involving skin incisions requiring various types of wound closure techniques, are performed in the world, with the majority resulting in a wound healing by primary intention [4].
Braided Polyamide Suture Coated with Chitosan- Citric Acid Biopolymer
In the last few years there has been a growing interest in the improvement of absorbable sutures. Quite recently, considerable attention has been paid to marketed non-absorbable sutures, which have undergone some improvements in their mechanical properties. However, there have been no new significant improvements in their physiological properties since their first use. Several researches have appeared in recent years verifying that the presence of suture significantly enhances the susceptibility of surrounding tissues to infection [5,6]. Indeed, many distressing complications such as infection, wound disruption and chronic sinus formation occur in sutured wound. Previous studies indicate that suture materials vary in their propensity to produce bacterial infection in surgical wounds. The physical configuration of the suture thread has been suggested to be an important factor in determining its susceptibility to surgical infection.4 Thus, multifilament suture have been known for their compliance leading to secure and compact knots. However, their intrinsic surface roughness and capillarity increase the potential of wound infection [7]. Thus, sutures in multifilament form result in higher wound infection than the same sutures in monofilament form. To solve this problem, many researchers have proposed various methods to develop antimicrobial non-absorbable multifilament sutures by using antimicrobial agents, compounds that have the ability to kill or inhibit the growth of microbes, thus preventing infection [8-10]. These include: antibiotics that are capable of inhibiting life processes of all foreign organisms and antibacteria that kill and prevent the growth of bacteria.
Several publications have appeared in recent years, documenting several approaches to the development of antimicrobial sutures [11,12]. For several years, great effort has been devoted to the study of the incorporation of silver metal on the surface of suture and conventional antibiotics, such as neomycin palmitate, penicillin and sulfonamide, onto suture surface by impregnation. Previous research have shown that the antimicrobial activity in sutures can be achieved by blending or incorporating volatile or non-volatile antimicrobial agent while processing, coating or graft polymerization followed by immobilization of antimicrobial agents onto the suture surface [13-15]. Coating has been the most common technique used for applying the antibacterial agents on the textile surface. The antibacterial agents have been connected to the surface by physical bonds or fixed to the molecular chains of the fiber by using crosslinking agents. Focus on polyamide suture, antibiotic sutures have been developed by grafting acrylic acid onto suture surface followed by antibiotic fixation [16]. Antibiotic monofilament suture was prepared by doping with iodine and antimicrobial properties against E coli and S aureus were tested by zone of inhibition method. Drug doxycycline has been also used to obtain antibiotic suture. However, all of the previous studies do not take into account to produce commercial sutures because the frequent use of antibiotics can avoid long-term, ineffective, systemic antibiotics and reduce the risk of microbial resistant generation [17]. Based on this approach, only antibacterial compounds are recommended and used for producing suture that inhibit bacterial proliferation.
In 2004, Ethicon Inc. developed and marketed the first antibacterial sutures on the market called Vicryl Plus, Monocryl Plus and PDS II Plus. These absorbable sutures have been coated with Triclosan and have an antibacterial effect against S Aureus, S Epidermidis, Meticillin, E coli and K pneumoniae. Following the commercialization of Vicryl plus suture by Ethicon Inc, several works have been conducted and confirmed the effectiveness of this suture. Alonso et al. [18] and Rothenburger et al. [19] have also proved the antibacterial effect of this suture against S aureus and S epidermidis and Marzo et al. [20] have shown a decrease of infection with P aeruginosa germs. The success of these sutures has been also confirmed by statistical survey, proving that the use of antibacterial sutures leads to reduction in the infection frequency [21-23]. Furthermore, the use of this suture contributes to budgetary gain of $ 1.5 million in a medical center [24].
Despite the efficiency of Triclosan, which is the most and only used antibacterial product for marketed sutures, this product has several limitations, which can cause complications. In fact, Clayton et al. have shown that Triclosan can negatively affect immune functions and the reproducibility of the cells [25]. For this reason, many attempts are recommended new antibacterial products to be used for the development of antimicrobial sutures. With this goal, in recent years, research on new antibacterial biomaterials has become very popular. Recent research reports the development of new antibacterial suture threads that show better results than Vicryl Plus [26]. Referring to the sources in general, chitosan is a biomaterial well used in biomedical field because of beneficial properties for wound healing and particularly for its antibacterial effect [27]. Several studies have confirmed the effect of chitosan as an antibacterial agent [28-33]. It is one of many antibacterial products widely present in nature. It is not affected by sterilization with ethylene oxide (EO), and keeps its antibacterial property after this treatment [34,35]. That is why chitosan is ideal for use on the development of antibacterial suture, which is subjected to sterilization by EO in the last step of manufacturing process such as polyamide suture.
The literature shows a variety of approaches permitting to apply chitosan on suture surface. Antibacterial polyester sutures have been prepared by grafting chitosan to the suture surface using acrylic acid. Much research has been done to develop chitosan coated polylactic acid (PLA) and silk sutures. Viju and Thilagavathi [36] have studied the effect of this treatment on the mechanical properties and the surface state of the braided antibacterial silk sutures. They reported a slight improvement in the suture mechanical and antibacterial properties. Nonetheless, the used dipping process does not make it possible to have a uniform treatment on the suture surface and sutures can stick between them in the bath. Although several studies have been conducted in order to develop antibacterial non-absorbable suture, today, no antibacterial non-absorbable sutures are presented in market and only antibacterial absorbable sutures are produced and marketed by Ethicon Inc. With this goal, in this study we explore the possibility of use of chitosan for the development of new antibacterial nonabsorbable polyamide suture [37]. Thus, the aim of the present study was to determine optimal manufacturing conditions permitting to attain this purpose. Biopolymer compounds and non-toxic products suitable for implantation in human body will be used. Appropriate method of applying biopolymers compounds on suture surface will be presented. Chemical reactions between different biopolymer compounds and polyamides will be investigated. Mechanical, antibacterial and surface properties of sutures will be investigated in order to determine best manufacturing conditions to obtain the best antibacterial suture.
This paper is a modest contribution to the ongoing discussions on the development of antibacterial non absorbable sutures, particularly the possibility of use of chitosan for the development of antibacterial sutures. The main purpose of this paper is the development of new process for producing antibacterial PA 6-6 braided sutures. PAD-dry process was used in order to apply uniform multilayers of chitosan-CA biopolymer on suture surface. This paper has clearly presented an investigation of chemicals and mechanical properties of suture. For study purpose, chemical characteristics of applied biopolymer coating on suture surface are determined by using ATR-IF. It has been demonstrated that many eventual bonds between compounds present in coating solutions and PA-66 may occur. The existence of these bonds implies the fixation of biopolymer coating on suture surface. Suture surface has been investigated by using image analysis (SEM image) and friction difference test (FCD-mean). These experiments have demonstrated that uniform surface may be obtained by progressively applying coating solution containing little amount of chitosan on suture surface. We have also found that the developed coating process has not affected tensile properties of suture. In fact, TS and KPS still meet USP requirement. Antibacterial activity of developed sutures has been also tested against four colonies and the optimal conditions permitting to have an antibacterial effect and a smooth surface have been determined. From the research that has been carried out, it is possible to conclude that the best suture may be obtained by applying three layers of chitosan-CA biopolymer containing 1% of chitosan and polymerized at a temperature equal to 160oC. Indeed, these sutures have shown remarkable antibacterial effect against E coli (gram-negative) and P aeruginosa (gram-negative). Based on these results, it can be concluded that research conducted into development of antibacterial suture in vitro has been very successful. However, the main limit of the experimental results is that suture performance efficiency has not been conducted in vivo. Clearly, further research will be desirable to validate the obtained result in vivo. In an effort to prove coating film stability against friction, realized test is presented in the Supplementary
Silk sutures treated with natural fungal extract
The most crucial requirements of suture materials are physical and mechanical properties, handling properties, biocompatibility, and antimicrobial nature [38]. Till date, there is no single suture material which can fulfill all the crucial requirements of sutures [39]. The present surgeon has several choices of suture material available and he may choose them based on availability and his familiarity. Silk, a natural non-absorbable suture material has been used as biomedical suture for centuries due to its advantageous characteristics. However, one of the major problems associated with the silk is its poor microbe resistance characteristics. Several researchers have used different antimicrobial agents onto silk sutures to impart microbe resistance characteristics. Researchers have also used silver doped bioactive glass powder to coat silk surgical suture [40]. Recently, studies on the effect of chitosan coating on the characteristics of silk sutures. Another study on tetracycline coating on silk sutures was carried out and they investigated the effect of tetracycline treatment on silk suture properties [41].
Recently, antimicrobial finishing of textiles using microbial dyes have received greater attention as they require less labour, land, and cost effective solvents for extraction as opposed to higher plant materials. In this study, silk sutures are treated with Thermomyces, a natural fungal extract and its effect on the properties of silk sutures such as antimicrobial activity, friction, tenacity and knot strength are studied.
Silk suture produced was treated with natural fungal extract at optimum concentration and the effects of natural fungal treatment on the suture properties were studied. The result showed that the tenacity and knot strength of silk braided sutures increased compared to the untreated silk suture. The frictional properties of both the fungal treated silk suture and the untreated silk suture were determined by the dynamic coefficient of friction and there is a slight reduction in frictional value found in the treated silk suture compared to the untreated silk suture [42]. The uniform deposition of natural fungal pigment on to the surface of the silk braided suture was confirmed by Scanning Electron Microscopy. The antibacterial activity of fungal treated silk braided suture at optimum concentration against S. aureus and E. coli is found to be good compared to the untreated silk suture. The result suggests that the silk suture treated with optimum concentration of the natural fungal pigment is appropriate to retard the exponential growth of S. aureus, a gram-positive bacterium and E. coli a gramnegative bacterium and hence silk sutures can be developed with the required characteristics for healthcare applications.
Sutures for skin closure in controlling surgical site infections
Skin wounds are at risk of SSI and therefore may lead to increased morbidity, delayed recovery and prolonged hospital stay [43]. The prevalence of SSI in the developed world is variable but reported figures are estimated at around 5% [44,45]. The development of SSI is a multifactorial phenomenon, which requires a multimodal approach to prevent and treat it in a timely manner to avoid financial, psychological and health-related quality of life consequences. Various predisposing aetiopathological factors for SSI include immune supression, nutritional deficiencies, hypoproteinemias, congestive cardiac failure, hepatic failure, renal failure, use of steroids, chemotherapy agents, steroids and diabetes mellitus [46-49]. In additions to these factors, wound contamination, contaminated instruments, surgical technique and sutures used to close skin have also been reported to be responsible for SSI and cosmetic outcomes [50-52]. The prevention of the SSI by various invasive and non-invasive interventions is the most common measure surgeons and other healthcare professional advocate to tackle the problem of SSI. This includes use of prophylactic antibiotics and various other multimodal approaches already reported in the medical literature [53-56]. Triclosan [5-chloro-2- (2,4-dichlorophenoxy)phenol] is a broad-spectrum bacteriocidal agent that has been used for more than 40 years in various products, such as toothpaste and soaps. Higher concentrations of triclosan work as a bactericide by attacking different structures in the bacterial cytoplasm and cell membrane [57].
At lower concentrations, triclosan acts as bacteriostatic agent, binding to enoyl-acyl reductase (ENR), a product of the Fab I gene and thus inhibiting fatty acid synthesis [58,59]. Use of triclosancoated sutures should theoretically result in the reduction of SSI. Several studies have shown a reduction in the number of bacteria in vitro and also of wound infections in animals [60-62]. The objective of this article is to systematically analyse the randomized, controlled trials comparing the use of triclosan-coated antibacterial sutures (ABS) versus simple sutures (SS) for skin closure in controlling the SSIs. We aimed to include only those trials in which the SSI was investigated as a primary outcome regardless the surgical specialty. The SSI was the primary outcome of this study, whereas postoperative complications, duration of the operation and length of the hospital stay (if reported) were analysed as secondary outcome measures. Although our conclusion is based on the summated outcome of seven randomized, controlled trials, it should be considered cautiously because the quality of the majority of included trials was poor [63]. There is still a lack of stronger evidence to support the routine use of ABS but it can be considered an alternative and may initially be applied in selected groups of patients. A major, multicentre, randomized, controlled trial of high quality according to CONSORT guidelines is mandatory to validate these findings.
Conclusion
Antibacterial sutures should be used. The main objective of this study is the development of new non-absorbable antibacterial polyamide braided suture. This paper suggests new coating process that leads to obtain suture uniformly covered by antibacterial film enclosing chitosan, which is known for its antibacterial benefit. Mechanical properties and surface morphology of developed sutures were investigated by using mechanical tests. Sutures surfaces were also examined by scanning electron microscope, to perceive spreading of coating product on suture surface. In order to identify potential reactions between chemical compounds present in coating solution and suture material, sutures were analyzed by ATR-IF spectroscopy. It has been demonstrated that many eventual bonds between compounds present in coating solutions and polyamide macromolecular chain may occur. The existence of these bonds implies the fixation of biopolymer coating on suture surface. It has been demonstrated that uniform surface may be obtained by progressively applying coating solution containing little amount of chitosan on suture surface. We have also found that developed coating process has not affected mechanical properties of suture, which still meet United States Pharmacopeia requirement. Finally, antibacterial effects against four colonies, very widespread in hospitals, were studied. Prominent antibacterial effects of braided polyamide suture against two gram-positive (S Aureus, S epidermidis) and two gram-negative (E coli and P aeruginosa) colonies are presented. Optimal result of best properties is obtained by applying three layers of biopolymer coating comprising 1% chitosan and 10% citric acid. The new developed suture coating process appears as a promising method for obtaining important antibacterial effect with smooth suture surface.
The result showed that the pigment concentration in the selected range has no significant effect on friction, tenacity and knot strength of silk sutures. Antimicrobial test results showed that as the pigment concentration increases the antimicrobial activity also increases against both E. coli and S. aureus bacteria. At 2.5% concentration, a zone of inhibition of 10 mm and 14 mm are observed against E. coli and S. aureus respectively. Silk suture treated with optimum concentration of the natural fungal pigment is appropriate to retard the exponential growth of S. aureus, a grampositive bacterium and E. coli a gram-negative bacterium and hence silk sutures can be developed with the required characteristics for healthcare applications. Randomized, controlled trials on surgical patients comparing the use of ABS for skin closure in controlling the surgical site infections were analysed systematically using RevMan and combined outcomes were expressed as odds ratios (OR) and standardized mean differences (SMD). Seven randomized, controlled trials evaluating 1631 patients were retrieved from electronic databases. There were 760 patients in the ABS group and 871 patients in the simple suture group. There was moderate heterogeneity among trials (Tau2= 0.12; chi2= 8.40, df = 6 [P<0.01]; I2= 29%). Therefore in the random-effects model, the use of ABS for skin closure in surgical patients was associated with a reduced risk of developing surgical site infections (OR, 0.16; 95% CI, 0.37, 0.99; z = 2.02; P<0.04) and postoperative complications (OR, 0.56; 95% CI, 0.32, 0.98 z = 2.04; P=0.04). The durations of operation and lengths of hospital stay were similar following the use of ABS and SS for skin closure in patients undergoing various surgical procedures. Use of ABS for skin closure in surgical patients is effective in reducing the risk of surgical site infection and postoperative complications. ABS is comparable with SS in terms of length of hospital stay and duration of operation
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