Hydroxypropylmethylcellulose (HPMC) and hydroxypropylcellulose (HPC) are two polymers commonly used in various industries including pharmaceuticals, food, cosmetics and construction. Both are derivatives of cellulose and have similar chemical structures, but differ in their properties and applications.
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Chemical structure:
Hydroxypropyl methylcellulose (HPMC): HPMC is synthesized from natural cellulose through chemical modification of etherification. During this process, both hydroxyl groups of the cellulose molecule undergo substitution reactions. Methyl groups (-CH 3 ) were introduced to some of the hydroxyl groups, while hydroxypropyl groups (-CH 2 CH(OH)CH 3 ) were added to the remaining hydroxyl groups. This double substitution gives the polymer hydrophilic and hydrophobic properties, making it soluble in water and organic solvents.
Hydroxypropylcellulose (HPC): HPC, on the other hand, is produced by chemically modifying cellulose with propylene oxide. Unlike HPMC, which has introduced methyl groups, HPC mainly contains hydroxypropyl groups (-CH2CH(OH)CH3). This substitution results in an increased solubility of the polymer in organic solvents compared to native cellulose but retains some hydrophilic properties due to the presence of hydroxyl groups.
characteristic:
Solubility: HPMC is soluble in cold and hot water, forming a clear, viscous solution. It exhibits a phenomenon called "thermal gelation" in which the solution undergoes a reversible phase transition from liquid to gel as the temperature increases. HPC is also soluble in water, but to a lesser extent than HPMC. It forms colloidal solutions in water and exhibits better solubility in organic solvents such as ethanol, isopropyl alcohol and acetone.
Viscosity: HPMC and HPC are available in various viscosity grades for a wide range of applications. However, HPMC generally has a higher viscosity than HPC at equivalent concentrations, making it suitable for applications requiring thicker gels or coatings.
Film Formation: HPMC dries to form flexible, transparent films suitable for applications such as coatings, films and tablets. HPC also has film-forming properties but may produce films with slightly different properties, such as increased flexibility or moisture resistance based on degree of substitution and molecular weight.
Thermal Stability: HPMC generally exhibits good thermal stability, maintaining its performance over a wide temperature range. HPC also exhibits thermal stability but may undergo degradation at higher temperatures, especially in the presence of oxygen.
Manufacturing process:
HPMC: The production of HPMC involves several steps, including etherification of cellulose with propylene oxide to introduce hydroxypropyl groups, followed by methylation with methyl chloride to add methyl groups. The resulting product was then purified and dried to obtain the final HPMC powder.
HPC: HPC is typically produced by direct etherification of cellulose with propylene oxide, thereby introducing hydroxypropyl groups into the cellulose backbone. The degree of substitution and molecular weight of the polymer can be controlled by adjusting reaction conditions such as temperature, pressure and reaction time.
application:
HPMC: HPMC is widely used in pharmaceutical formulations as binders, disintegrants, controlled release agents and thickeners in tablet coatings. It is also used in construction materials such as cement-based mortars and plasters as a rheology modifier and water retaining agent. Additionally, HPMC is used in personal care products, food additives, and as a thickener in industrial processes.
HPC: HPC is primarily used in pharmaceuticals as a binder, film former, and viscosity enhancer in tablet formulations. Its solubility in organic solvents makes it suitable for use in coatings, especially enteric coatings and sustained-release formulations. HPC is also used in personal care products, food applications, and as a thickening agent in industrial processes, but to a lesser extent than HPMC.
advantage:
HPMC: The main advantages of HPMC include its versatility, biocompatibility, and ease of use in a variety of formulations. It has excellent film-forming properties, thermal stability and controlled release properties, making it a first choice for pharmaceutical and construction applications.
HPC: HPC offers advantages such as improved solubility in organic solvents, making it suitable for applications where water solubility is not required. It also provides good film-forming properties, viscosity control and compatibility capabilities with other excipients in pharmaceutical formulations.
Although HPMC and HPC have similarities in chemical structure as cellulose derivatives, they exhibit differences in properties, solubility, manufacturing processes, applications, and advantages. Understanding these differences is critical to selecting the right polymer for specific formulations and applications in different industries. Both polymers offer unique advantages and play important roles in pharmaceuticals, construction, personal care products and other industrial sectors, contributing to their widespread use and versatility in different applications.
Product Description
Hydroxypropyl MethylCellulose (HPMC) are widely used in construction, pharmaceutical,food, cosmetic, detergent, paints, as thickener, emulsifier, film-former, binder, dispersing agent, protective colloids.
HPMC-Hydroxypropyl Methyl Cellulose and Methyl Hydroxyethyl Cellulose and non-ionic cellulose ether made by natural high polymer cellulose as raw material and series of chemical processing. They are odorless, tasteless and non-toxic white powder, which can be dissolved in cold water to form a transparent viscous solution. Processing thickening, binding, dispersing, emulsifying, film, coating, suspending, absorbing, gelling, surface activity, water maintaining and protective colloid properties
Product Parameters
Items
Technical data
Units
Appearance
White or off-white powder
Methoxy
19%~24%
%
Hydroxypropoxy
4%~12%
%
Viscosity range (2%,Brookfield)
300-
mPa.S
Viscosity range (1%, NDJ)
300-
mPa.S
Moisture
&#;5
%
PH Value
6-8Gel temperature
60-75
%
Packing Density
250 - 360
g/l
Product List
Model
Packing
Viscosity Brookfield 2% solution
Viscosity NDJ 2% solution
Hydroxypropylmethylcellulose (HPMC) and hydroxypropylcellulose (HPC) are two polymers commonly used in various industries including pharmaceuticals, food, cosmetics and construction. Both are derivatives of cellulose and have similar chemical structures, but differ in their properties and applications.
Chemical structure:
Hydroxypropyl methylcellulose (HPMC): HPMC is synthesized from natural cellulose through chemical modification of etherification. During this process, both hydroxyl groups of the cellulose molecule undergo substitution reactions. Methyl groups (-CH 3 ) were introduced to some of the hydroxyl groups, while hydroxypropyl groups (-CH 2 CH(OH)CH 3 ) were added to the remaining hydroxyl groups. This double substitution gives the polymer hydrophilic and hydrophobic properties, making it soluble in water and organic solvents.
Hydroxypropylcellulose (HPC): HPC, on the other hand, is produced by chemically modifying cellulose with propylene oxide. Unlike HPMC, which has introduced methyl groups, HPC mainly contains hydroxypropyl groups (-CH2CH(OH)CH3). This substitution results in an increased solubility of the polymer in organic solvents compared to native cellulose but retains some hydrophilic properties due to the presence of hydroxyl groups.
characteristic:
Solubility: HPMC is soluble in cold and hot water, forming a clear, viscous solution. It exhibits a phenomenon called "thermal gelation" in which the solution undergoes a reversible phase transition from liquid to gel as the temperature increases. HPC is also soluble in water, but to a lesser extent than HPMC. It forms colloidal solutions in water and exhibits better solubility in organic solvents such as ethanol, isopropyl alcohol and acetone.
Viscosity: HPMC and HPC are available in various viscosity grades for a wide range of applications. However, HPMC generally has a higher viscosity than HPC at equivalent concentrations, making it suitable for applications requiring thicker gels or coatings.
Film Formation: HPMC dries to form flexible, transparent films suitable for applications such as coatings, films and tablets. HPC also has film-forming properties but may produce films with slightly different properties, such as increased flexibility or moisture resistance based on degree of substitution and molecular weight.
Thermal Stability: HPMC generally exhibits good thermal stability, maintaining its performance over a wide temperature range. HPC also exhibits thermal stability but may undergo degradation at higher temperatures, especially in the presence of oxygen.
Manufacturing process:
HPMC: The production of HPMC involves several steps, including etherification of cellulose with propylene oxide to introduce hydroxypropyl groups, followed by methylation with methyl chloride to add methyl groups. The resulting product was then purified and dried to obtain the final HPMC powder.
HPC: HPC is typically produced by direct etherification of cellulose with propylene oxide, thereby introducing hydroxypropyl groups into the cellulose backbone. The degree of substitution and molecular weight of the polymer can be controlled by adjusting reaction conditions such as temperature, pressure and reaction time.
application:
HPMC: HPMC is widely used in pharmaceutical formulations as binders, disintegrants, controlled release agents and thickeners in tablet coatings. It is also used in construction materials such as cement-based mortars and plasters as a rheology modifier and water retaining agent. Additionally, HPMC is used in personal care products, food additives, and as a thickener in industrial processes.
HPC: HPC is primarily used in pharmaceuticals as a binder, film former, and viscosity enhancer in tablet formulations. Its solubility in organic solvents makes it suitable for use in coatings, especially enteric coatings and sustained-release formulations. HPC is also used in personal care products, food applications, and as a thickening agent in industrial processes, but to a lesser extent than HPMC.
advantage:
HPMC: The main advantages of HPMC include its versatility, biocompatibility, and ease of use in a variety of formulations. It has excellent film-forming properties, thermal stability and controlled release properties, making it a first choice for pharmaceutical and construction applications.
HPC: HPC offers advantages such as improved solubility in organic solvents, making it suitable for applications where water solubility is not required. It also provides good film-forming properties, viscosity control and compatibility capabilities with other excipients in pharmaceutical formulations.
Although HPMC and HPC have similarities in chemical structure as cellulose derivatives, they exhibit differences in properties, solubility, manufacturing processes, applications, and advantages. Understanding these differences is critical to selecting the right polymer for specific formulations and applications in different industries. Both polymers offer unique advantages and play important roles in pharmaceuticals, construction, personal care products and other industrial sectors, contributing to their widespread use and versatility in different applications.
Product Description
Hydroxypropyl MethylCellulose (HPMC) are widely used in construction, pharmaceutical,food, cosmetic, detergent, paints, as thickener, emulsifier, film-former, binder, dispersing agent, protective colloids.
HPMC-Hydroxypropyl Methyl Cellulose and Methyl Hydroxyethyl Cellulose and non-ionic cellulose ether made by natural high polymer cellulose as raw material and series of chemical processing. They are odorless, tasteless and non-toxic white powder, which can be dissolved in cold water to form a transparent viscous solution. Processing thickening, binding, dispersing, emulsifying, film, coating, suspending, absorbing, gelling, surface activity, water maintaining and protective colloid properties
Product Parameters
Items
Technical data
Units
Appearance
White or off-white powder
Methoxy
19%~24%
%
Hydroxypropoxy
4%~12%
%
Viscosity range (2%,Brookfield)
300-
mPa.S
Viscosity range (1%, NDJ)
300-
mPa.S
Moisture
&#;5
%
PH Value
6-8Gel temperature
60-75
%
Packing Density
250 - 360
g/l
Product List
Model
Packing
Viscosity Brookfield 2% solution
Viscosity NDJ 2% solution
HPMC AS300WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS200WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS150WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS100WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS300M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS200M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS170M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS150M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS100M
-mPa.s
-mPa.S
25KG/Woven Bag
Product Details Display
HPMC AS300WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS200WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS150WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS100WS
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS300M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS200M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS170M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS150M
-mPa.s
-mPa.S
25KG/Woven Bag
HPMC AS100M
-mPa.s
-mPa.S
25KG/Woven Bag
Product Details Display
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