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Answer: Hydroxypropyl Methylcellulose, in English, is abbreviated as HPMC or MHPC. It is also known as hydroxypropyl methyl cellulose, hydroxypropyl methylcellulose ether, Hypromellose, Cellulose 2-hydroxypropylmethyl, and Cellulose hydroxypropyl methyl ether, Hyprolose.

Hydroxypropyl Methyl Cellulose A Versatile Polysaccharide

HPMC is a modified form of cellulose, a natural polymer found abundantly in plant cell walls. The hydroxypropylation and methylation processes transform native cellulose into a water-soluble derivative. The hydroxypropyl part makes it more soluble in water, while the methyl group imparts stability and modifies its viscosity.

The FEEDAP Panel agrees with the approach of the ANS Panel that, although the data set available for the different celluloses is not complete and most of the studies were old and do not meet the current requirements of toxicological testing, the physico-chemical, structural, biological and kinetic similarities between the modified celluloses make it possible to apply a read-across approach among the different celluloses. Overall, the available information allows to conclude that the celluloses (as a group) are of low toxicological concern.

Do not touch the container tip to the eye, lid, or other skin.

Overall, the price of HPMC is a complex issue that is influenced by a variety of factors. Pharmaceutical companies and other stakeholders should carefully evaluate these factors and consider alternative options when making decisions related to the use of HPMC in their products and processes. By doing so, they can ensure that they are getting the best value for their money while also meeting regulatory requirements and promoting sustainability.

In addition to concrete and mortar, HPMC is also used in plastering, tile adhesives, and dry-mix products. Its film-forming characteristic makes it ideal for surface coatings, providing a smooth and durable finish. Furthermore, it acts as a binder in dry-mix products, ensuring uniform distribution and consistent performance.

With a busy life and little time this isn’t always possible.

What do I do if I miss a dose?

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Hydroxyethylcellulose (HEC), a semi-synthetic polymer derived from cellulose, is a versatile material with an array of uses across various industries due to its unique properties. Its chemical structure, characterized by the substitution of hydroxyethyl groups onto the cellulose backbone, imparts it with water solubility, non-toxicity, and the ability to form thick gels. This article explores the diverse applications of HEC in detail.

Hydroxypropyl Methylcellulose, often referred to as HPMC, is a non-ionic cellulose ether derived from natural cellulose. It is a versatile chemical compound commonly used in numerous industries, including construction due to its exceptional water retention, thickening, and film-forming abilities. In the context of tile adhesives, HPMC serves as a vital additive, enhancing the adhesive's performance and durability.

Anti-corrosion additives protect the steel reinforcement within the concrete, extending the lifespan of structures

There are data for microcrystalline cellulose (E 460), methyl cellulose (E 461), hydroxypropyl cellulose (E 463) and sodium carboxymethyl cellulose (E 466), which were tested in mice, rats, hamsters and/or rabbits with oral dosing or via gavage. As regards microcrystalline cellulose (E 460) studies have been conducted in rats (dietary exposure) with a mixture including guar gum or sodium carboxymethylcellulose (E 466) (15% in either case). The NOAEL for both maternal and developmental toxicity were the highest experimental dosages, i.e. 4,500 mg/kg bw (for mixture with guar gum) and 4,600 mg/kg bw (for mixture with sodium carboxymethyl cellulose). Methyl cellulose (E 461) was examined in mice, rats, hamsters and rabbits. In two different studies, pregnant mice were exposed via gavage (vehicle corn oil) to a dose range of 16-1,600 mg methyl cellulose (E 461)/kg bw per day from day 6 to 15 of gestation, followed by a caesarean section at day 17 of gestation. In the first study, maternal toxicity (increase in mortality and reduced pregnancy rate in the survivors) as well as retarded ossification in fetuses were noticed at the highest tested level, pointing to a NOAEL of 345 mg methyl cellulose (E 461) mg/kg bw per day (the last but one highest dosage) in mice. In the second study, no maternal toxicity and fetal abnormalities were observed in mice exposed up to 700 mg methyl cellulose (E 461) mg/kg bw per day. Rat studies (n = 2) were performed in pregnant dams exposed via gavage (vehicle corn oil) to a dose range of 16-1,320 mg methyl cellulose (E 461) mg/kg bw per day from day 6 to 15 of gestation followed by a caesarean section at day 20. In the first study (0, 13, 51, 285 or 1,320 mg methyl cellulose (E 461)/kg bw per day) the highest tested dosage resulted in no maternal toxicity but also in increased incidence of extra centres of ossification in vertebrae of fetuses from high dose dams; in a second rat study, the incidence of such alteration slightly increased in fetuses from the highest dosed group (1,200 mg methyl cellulose (E 461)/kg bw per day). Based on the above results, a NOAEL of 285 mg methyl cellulose (E 461) mg/kg bw per day could be identified in rats. No maternal or fetal toxicity was detected in Golden hamsters exposed via gavage (vehicle corn oil) up to 1,000 mg methyl cellulose (E 461) mg/kg bw per day from day 6 to 10 of gestation followed by a caesarean section at day 20. The study on rabbits was discarded due to poor experimental design. The only relevant developmental toxicity study with hydroxypropyl cellulose (E 463) (dissolved in 1% gum arabic solution) was performed in pregnant rats exposed via gavage from day 7 to 17 of gestation to 0, 200, 1,000 or 5,000 mg/kg bw test item and some of them subjected to caesarean sections at day 20. No treatment-related adverse effects were detected in dams or in the examined fetuses. A number of dams were allowed to deliver and no clinical, behavioural or morphological changes were observed in the examined pups. Their reproductive ability was seemingly not affected and no abnormalities were found in the F1-derived fetuses. The in utero exposure to the highest dose (5,000 mg/kg bw per day) may be considered as the NOAEL of methyl cellulose (E 461) for this study. No mortality, and no adverse effects were observed on implantation or on fetal survival in pregnant mice or rats dosed via gavage with up to 1,600 mg sodium carboxymethyl cellulose (E 466)/kg bw per day.

In conclusion, the thickening mechanism of hydroxyethyl cellulose is a complex interplay between its chemical structure, hydration, temperature, and concentration. Understanding these factors allows for precise control over the viscosity of HEC-based systems, making it an indispensable ingredient in various industries. Future research continues to unravel new aspects of HEC's behavior, potentially unlocking even more applications and optimizing its performance in existing ones.

HPMC is commonly used in the formulation of oral solid dosage forms such as tablets and capsules. One of the key properties of HPMC is its ability to act as a binder, which helps to hold the active pharmaceutical ingredients together and improve the cohesion of the tablet matrix. In addition, HPMC can also function as a film-former, coating agent, and controlled-release agent in drug formulations.

In conclusion, hydroxypropyl methylcellulose powder is a versatile material that finds applications across numerous sectors, including pharmaceuticals, construction, food, cosmetics, and paint. Its unique properties, such as water solubility, gelling ability, and film formation, coupled with its eco-friendly nature, make HPMC an indispensable component in modern industrial processes. As research continues to explore new applications, the significance of HPMC in various industries is expected to grow further.

The production of HPMC begins with the sourcing of high-quality cellulose, typically from cotton linters or wood pulp. These raw materials are chosen for their high cellulose content, ensuring a pure and efficient end product. The cellulose is then subjected to a series of chemical treatments to create the desired HPMC structure.

HPMC gilt als unbedenklich für den menschlichen Verzehr. Da HPMC vom Körper wie ein wasserlöslicher Ballaststoff unverdaut ausgeschieden wird, kann er ohne Bedenken und ohne Einschränkung zu sich genommen werden. Normalerweise gibt es für die Verträglichkeit von Lebensmittelzusatzstoffen einen sogenannten ADI-Wert (acceptable daily intake). Dieser Wert gibt die Tagesdosis an, die bei lebenslanger täglicher Einnahme als medizinisch unbedenklich betrachtet wird. Der ADI-Wert wird durch das Bundesinstitut für Risikobewertung sowie der Europäischen Behörde für Lebensmittelsicherheit (EFSA) festgelegt. Für HPMC gibt es keine Beschränkung der Höchstmenge, also auch keinen ADI-Wert.

Lediglich bei der Einnahme sehr hoher Mengen kann eine abführende Wirkung eintreffen.

Cellulose, a complex carbohydrate primarily found in plant cell walls, is the most abundant organic polymer on Earth. HEC is synthesized by reacting cellulose with ethylene oxide, introducing hydroxyethyl groups along the cellulose backbone. This modification enhances the water solubility and improves the overall characteristics of the original cellulose.

The global redispersible polymer powder market is highly competitive, with key players continually investing in research and development to introduce innovative products. Companies like Wacker Chemie AG, BASF SE, and Dow Chemical Company, among others, are instrumental in shaping the market dynamics through their extensive product portfolios and global reach.

In conclusion, mortar adhesive additives are not just enhancers but transformers in the world of construction. They provide tailor-made solutions to address various challenges faced on construction sites, from improving bonding strength and workability to promoting sustainability and resilience. With continuous research and development, the range and effectiveness of these additives are only set to expand, further pushing the boundaries of construction efficiency and durability.

4. **Local Suppliers** For smaller quantities or more personalized service, consider local chemical supply stores. While their inventory might be limited, they can offer quick delivery and hands-on assistance.

In conclusion, hydroxyethyl cellulose is a versatile polymer with a wide range of applications in various industries. Its high viscosity, thickening properties, and stability make it an indispensable ingredient in pharmaceuticals, cosmetics, food, and construction products. If you are looking for hydroxyethyl cellulose for sale, there are numerous suppliers offering high-quality HEC products to meet your needs and help you create superior formulations.

Hydroxypropylmethyl cellulose is a cellulose ether with both methyl and hydroxypropyl functional group substitutions. Hydroxypropylmethyl cellulose (HPMC) is a nonionic thermoplastic polymer that dissolves in water to produce a solutions with a wide range in viscosity. It has greater gelling capacity than hydroxypropyl cellulose (HPC) and is more tolerant to salts and additives. HPMC is used as a thickening agent, stabilizer, emulsifier and film forming agent. Aging studies indicate that HPMC has very good stability with negligible discoloration or weight loss (Feller and Wilt 1990).

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HEC is also used in the food industry as a stabilizer and thickener hydroxy ethyl cellulose uses. It is commonly used in sauces, dressings, and desserts to enhance their texture and shelf life. HEC helps to prevent syneresis, or weeping, in frozen foods and provides a smooth, creamy texture to ice cream and other frozen desserts.

In conclusion, the integration of HPMC in gypsum plaster is a strategic move that optimizes the performance, durability, and environmental impact of the material. It is a testament to the continuous innovation in the construction industry, striving to improve materials while preserving resources. The synergy between HPMC and gypsum plaster underscores the potential of science and technology in revolutionizing traditional building materials, leading to more efficient, sustainable, and aesthetically pleasing construction solutions.

In conclusion, the price of hydroxyethyl cellulose is a complex interplay of raw material availability, production costs, market demand, logistical challenges, quality standards, and environmental considerations. Understanding these factors allows stakeholders to navigate the market more effectively and make informed decisions about their investments in this multifaceted compound.

3. What are the dissolution methods of hydroxypropyl methyl cellulose (HPMC)?

Cellulose, being an insoluble substance, has limited direct usability. However, HPMC, through chemical modification, acquires unique properties that make it versatile and useful. The hydroxypropyl part of the acronym refers to the addition of hydroxypropyl groups, while methylcellulose signifies the presence of methyl groups. These alterations enhance its solubility in water, making it a valuable ingredient in various applications.

One of the key benefits of redispersible powder polymer is its ability to improve the workability and durability of construction materials. When added to mortar or cement, it enhances the bond strength, flexibility, and water resistance of the mix. This results in a more reliable and long-lasting finished product that can withstand the harsh conditions of construction sites.

Overall, the versatility and broad range of applications of HPMC make it an indispensable material in many industries. Its unique properties and functionality make it an ideal choice for a wide variety of products and processes. As demand for HPMC continues to grow, manufacturers are constantly working to improve their production processes and develop new applications for this valuable polymer.

In the food industry, HPMC serves as a thickener, emulsifier, texturizer, and stabilizer. It helps improve the texture and mouthfeel of ice cream, sauces, and dressings. Moreover, HPMC's film-forming characteristics are utilized in confectionery products, where it helps create a smooth, non-sticky surface on breath mints and other candies. The use of HPMC also extends shelf life by preventing dehydration and maintaining product integrity.