OrthoLite’s advanced proprietary polyurethane formula with recycled rubber content delivers a combination of benefits unmatched by any other insole manufacturer.

Long-Term Cushioning

Unlike traditional insoles, the compression set of OrthoLite insoles is less than 5% over time so the cushioning and fit never change inside the shoe, providing maximum comfort every time you put your shoes on.

High-Level Breathability

OrthoLite’s open-cell PU foam is 95% to 100% breathable, allowing air to circulate in and around the insole, keeping the foot cooler inside the shoe.

Moisture Management

The unique open-cell structure of OrthoLite insoles creates a moisture management system, helping to move moisture away from the foot to provide a cooler, drier, healthier shoe environment.

Antimicrobial Function

A patented salt-based antimicrobial is added to all OrthoLite foams to fight against the presence of fungus, bacteria and odor. The antimicrobial inhibits the buildup of the bacterial fungi associated with the cause of odor.

Washable

OrthoLite insoles are machine washable, coming out like new every time while maintaining all of their performance benefits after washing.

 Lightweight

OrthoLite insoles are lightweight, enhancing the performance of the shoes with airy comfort.

Synthetic latex is a man-made molecular copy of natural latex. The scientific name for this compound is Styrene-Butadiene (SBR).

Styrene is named for “styrax”, the resin from a Turkish tree. Low levels of styrene occur naturally in many kinds of plants as well as a variety of foods such as fruits, vegetables & nuts.

Butadiene is produced by dehydration of butane obtained from petroleum. Butadiene is also used in the manufacture of latex paints and nylon fibers used in rope and clothing.

Synthetic Latex is extremely uniform at the molecular level, so sleep products will have greater durability than those made solely with Natural Latex. However, what you gain in durability you lose in feel and sleep benefits as compared to Natural Latex.

OrthoLite’s advanced proprietary polyurethane formula with recycled rubber content delivers a combination of benefits unmatched by any other insole manufacturer.

Long-Term Cushioning

Unlike traditional insoles, the compression set of OrthoLite insoles is less than 5% over time so the cushioning and fit never change inside the shoe, providing maximum comfort every time you put your shoes on.

High-Level Breathability

OrthoLite’s open-cell PU foam is 95% to 100% breathable, allowing air to circulate in and around the insole, keeping the foot cooler inside the shoe.

Moisture Management

The unique open-cell structure of OrthoLite insoles creates a moisture management system, helping to move moisture away from the foot to provide a cooler, drier, healthier shoe environment.

Antimicrobial Function

A patented salt-based antimicrobial is added to all OrthoLite foams to fight against the presence of fungus, bacteria and odor. The antimicrobial inhibits the buildup of the bacterial fungi associated with the cause of odor.

Washable

OrthoLite insoles are machine washable, coming out like new every time while maintaining all of their performance benefits after washing.

 Lightweight

OrthoLite insoles are lightweight, enhancing the performance of the shoes with airy comfort.

Synthetic latex is a man-made molecular copy of natural latex. The scientific name for this compound is Styrene-Butadiene (SBR).

Styrene is named for “styrax”, the resin from a Turkish tree. Low levels of styrene occur naturally in many kinds of plants as well as a variety of foods such as fruits, vegetables & nuts.

Butadiene is produced by dehydration of butane obtained from petroleum. Butadiene is also used in the manufacture of latex paints and nylon fibers used in rope and clothing.

Synthetic Latex is extremely uniform at the molecular level, so sleep products will have greater durability than those made solely with Natural Latex. However, what you gain in durability you lose in feel and sleep benefits as compared to Natural Latex.

Polyurethane (PUR and PU) is a polymer composed of a chain of organic units joined by carbamate (urethane) links. While most polyurethanes are thermosetting polymers that do not melt when heated, thermoplastic polyurethanes are also available.

Polyurethane polymers are traditionally and most commonly formed by reacting a di- or polyisocyanate with a polyol. Both the isocyanates and polyols used to make polyurethanes contain on average two or more functional groups per molecule.

Some noteworthy recent efforts have been dedicated to minimizing the use of isocyanates to synthesize polyurethanes, because the isocyanates raise severe toxicity issues. Non-isocyanate based polyurethanes (NIPUs) have recently been developed as a new class of polyurethane polymers to mitigate health and environmental concerns.

Polyurethane products often are simply called “urethanes”, but should not be confused with ethyl carbamate, which is also called urethane. Polyurethanes neither contain nor are produced from ethyl carbamate.

Polyurethanes are used in the manufacture of flexible, high-resilience foam seating; rigid foam insulation panels; microcellular foam seals and gaskets; durable elastomeric wheels and tires (such as roller coaster and escalator wheels); automotive suspension bushings; electrical potting compounds; high performance adhesives; surface coatings and surface sealants; synthetic fibers (e.g., Spandex); carpet underlay; hard-plastic parts (e.g., for electronic instruments); hoses and skateboard wheels.

Polyurethanes are produced by mixing two or more liquid streams. The polyol stream contains catalysts, surfactants, blowing agents and so on. The two components are referred to as a polyurethane system, or simply a system. The isocyanate is commonly referred to in North America as the 'A-side' or just the 'iso'. The blend of polyols and other additives is commonly referred to as the 'B-side' or as the 'poly'. This mixture might also be called a 'resin' or 'resin blend'. In Europe the meanings for 'A-side' and 'B-side' are reversed. Resin blend additives may include chain extenders, cross linkers, surfactants, flame retardants, blowing agents, pigments, and fillers. Polyurethane can be made in a variety of densities and hardnesses by varying the isocyanate, polyol or additives.

Fully reacted polyurethane polymer is chemically inert. No exposure limits have been established in the U.S. by OSHA (Occupational Safety and Health Administration) or ACGIH (American Conference of Governmental Industrial Hygienists). It is not regulated by OSHA for carcinogenicity. Polyurethane polymer is a combustible solid and can be ignited if exposed to an open flame. Decomposition from fire can produce mainly carbon monoxide, and trace nitrogen oxides and hydrogen cyanide.

Liquid resin blends and isocyanates may contain hazardous or regulated components. Isocyanates are known skin and respiratory sensitizers. Additionally, amines, glycols, and phosphate present in spray polyurethane foams present risks.[32]

In the United States, additional health and safety information can be found through organizations such as the Polyurethane Manufacturers Association (PMA) and the Center for the Polyurethanes Industry (CPI), as well as from polyurethane system and raw material manufacturers. Regulatory information can be found in the Code of Federal Regulations Title 21 (Food and Drugs) and Title 40 (Protection of the Environment). In Europe, health and safety information is available from ISOPA,[33] the European Diisocyanate and Polyol Producers Association.

The methods of manufacturing polyurethane finished goods range from small, hand pour piece-part operations to large, high-volume bunstock and boardstock production lines. Regardless of the end-product, the manufacturing principle is the same: to meter the liquid isocyanate and resin blend at a specified stoichiometric ratio, mix them together until a homogeneous blend is obtained, dispense the reacting liquid into a mold or on to a surface, wait until it cures, then demold the finished part.

Polyurethane (PUR and PU) is a polymer composed of a chain of organic units joined by carbamate (urethane) links. While most polyurethanes are thermosetting polymers that do not melt when heated, thermoplastic polyurethanes are also available.

Polyurethane polymers are traditionally and most commonly formed by reacting a di- or polyisocyanate with a polyol. Both the isocyanates and polyols used to make polyurethanes contain on average two or more functional groups per molecule.

Some noteworthy recent efforts have been dedicated to minimizing the use of isocyanates to synthesize polyurethanes, because the isocyanates raise severe toxicity issues. Non-isocyanate based polyurethanes (NIPUs) have recently been developed as a new class of polyurethane polymers to mitigate health and environmental concerns.

Polyurethane products often are simply called “urethanes”, but should not be confused with ethyl carbamate, which is also called urethane. Polyurethanes neither contain nor are produced from ethyl carbamate.

Polyurethanes are used in the manufacture of flexible, high-resilience foam seating; rigid foam insulation panels; microcellular foam seals and gaskets; durable elastomeric wheels and tires (such as roller coaster and escalator wheels); automotive suspension bushings; electrical potting compounds; high performance adhesives; surface coatings and surface sealants; synthetic fibers (e.g., Spandex); carpet underlay; hard-plastic parts (e.g., for electronic instruments); hoses and skateboard wheels.

Polyurethanes are produced by mixing two or more liquid streams. The polyol stream contains catalysts, surfactants, blowing agents and so on. The two components are referred to as a polyurethane system, or simply a system. The isocyanate is commonly referred to in North America as the 'A-side' or just the 'iso'. The blend of polyols and other additives is commonly referred to as the 'B-side' or as the 'poly'. This mixture might also be called a 'resin' or 'resin blend'. In Europe the meanings for 'A-side' and 'B-side' are reversed. Resin blend additives may include chain extenders, cross linkers, surfactants, flame retardants, blowing agents, pigments, and fillers. Polyurethane can be made in a variety of densities and hardnesses by varying the isocyanate, polyol or additives.

Fully reacted polyurethane polymer is chemically inert. No exposure limits have been established in the U.S. by OSHA (Occupational Safety and Health Administration) or ACGIH (American Conference of Governmental Industrial Hygienists). It is not regulated by OSHA for carcinogenicity. Polyurethane polymer is a combustible solid and can be ignited if exposed to an open flame. Decomposition from fire can produce mainly carbon monoxide, and trace nitrogen oxides and hydrogen cyanide.

Liquid resin blends and isocyanates may contain hazardous or regulated components. Isocyanates are known skin and respiratory sensitizers. Additionally, amines, glycols, and phosphate present in spray polyurethane foams present risks.[32]

In the United States, additional health and safety information can be found through organizations such as the Polyurethane Manufacturers Association (PMA) and the Center for the Polyurethanes Industry (CPI), as well as from polyurethane system and raw material manufacturers. Regulatory information can be found in the Code of Federal Regulations Title 21 (Food and Drugs) and Title 40 (Protection of the Environment). In Europe, health and safety information is available from ISOPA,[33] the European Diisocyanate and Polyol Producers Association.

The methods of manufacturing polyurethane finished goods range from small, hand pour piece-part operations to large, high-volume bunstock and boardstock production lines. Regardless of the end-product, the manufacturing principle is the same: to meter the liquid isocyanate and resin blend at a specified stoichiometric ratio, mix them together until a homogeneous blend is obtained, dispense the reacting liquid into a mold or on to a surface, wait until it cures, then demold the finished part.