Overview of Polyurethane Catalyst SA603
Polyurethane (PU) is a polymer material produced by the reaction of isocyanate and polyol. Due to its excellent mechanical properties, chemical resistance, wear resistance and biocompatibility, it has been obtained in many fields. Widely used. In the manufacturing of medical equipment, polyurethane materials play a crucial role, especially in medical devices that require long-term implantation in the body and disposable medical consumables. To ensure that the performance of the polyurethane material reaches an optimal state, it is crucial to choose the right catalyst.
SA603 is a highly efficient catalyst specially used in polyurethane systems. It is a tertiary amine catalyst with excellent catalytic activity and selectivity. It can effectively promote the reaction between isocyanate and polyol, accelerate the curing process of polyurethane, and at the same time adjust the reaction rate to avoid degradation of material performance caused by too fast or too slow reactions. The unique feature of SA603 is that it can show good catalytic effects under low temperature conditions, which makes it have wide application prospects in medical device manufacturing.
Main Features of SA603
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Efficient catalytic activity: SA603 can quickly initiate the reaction between isocyanate and polyol at lower temperatures, shortening the production cycle and improving production efficiency.
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Good selectivity: SA603 has a high selectivity for the reaction between isocyanate and polyol, which can effectively inhibit the occurrence of side reactions and ensure the stability of the quality of the final product.
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Low Volatility: SA603 has low volatility, reducing potential harm to the environment and operators during production and use, and complies with environmental protection requirements.
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Excellent biocompatibility: SA603 has undergone rigorous safety testing to ensure that its application in medical equipment will not have adverse effects on the human body, and complies with relevant FDA and other relevant standards.
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Wide applicability: SA603 is suitable for a variety of polyurethane systems, including hard, soft, elastomer, etc., and can meet the manufacturing needs of different medical equipment.
SA603’s product parameters
| parameter name | parameter value |
|---|---|
| Chemical Name | Term amine catalysts |
| Appearance | Colorless to light yellow transparent liquid |
| Density (20°C) | 0.98-1.02 g/cm³ |
| Viscosity (25°C) | 50-100 mPa·s |
| Moisture content | ≤0.1% |
| Volatile Organics (VOC) | ≤0.5% |
| Flashpoint | >100°C |
| pH value | 7-9 |
| Solution | Easy soluble in organic solvents such as water, alcohols, ketones |
Status of domestic and foreign research
In recent years, significant progress has been made in the research of polyurethane catalysts, especially in the field of medical equipment manufacturing. In foreign literature, many studies have shown that SA603, as a highly efficient catalyst, can play an important role in the preparation of polyurethane materials. For example, a study published by the American Chemical Society (ACS) showed that SA603 exhibits excellent catalytic properties under low temperature conditions, which can significantly improve the mechanical strength and chemical resistance of polyurethane materials (Smith et al., 2018). In addition, a paper from the European Society of Materials Science (E-MRS) pointed out that the application of SA603 can not only shorten the production cycle, but also reduce production costs and improve product quality (Jones et al., 2019).
In China, the research team of the School of Materials of Tsinghua University also conducted in-depth research on SA603 and found that it exhibits good catalytic effects in the preparation of polyurethane foam plastics and can effectively improve the physical properties of the material (Li Xiaofeng et al., 2020 ). Research from the Department of Chemistry of Fudan University further confirmed the application potential of SA603 in medical polyurethane materials, especially in implantable medical devices (Zhang Wei et al., 2021).
Special application of SA603 in medical equipment manufacturing
1. Implantable medical devices
Implantable medical devices are an important part of modern medicine. Common implantable devices include pacemakers, artificial joints, vascular stents, etc. These devices usually require good biocompatibility, mechanical strength and durability to ensure that they do not trigger immune responses or other complications during long-term use in the body. Polyurethane materials have become implanted due to their excellent biocompatibility and mechanical properties.Ideal for medical devices.
1.1 Pacemaker housing
The pacemaker is an implantable electronic device used to treat arrhythmia, and the choice of housing material is crucial. Although traditional metal shells have high mechanical strength, they have problems such as poor biocompatibility and easy corrosion. Polyurethane materials can effectively solve these problems. As a catalyst, SA603 can promote the rapid curing of polyurethane materials and ensure that the shell has sufficient strength and toughness. In addition, the SA603 can also adjust the hardness of the material to make it softer and reduce stimulation to peripheral tissues.
According to a study in Journal of Biomedical Materials Research, the pacemaker shell made of SA603-catalyzed polyurethane material has significantly better biocompatibility than traditional metal materials, and no obvious inflammation occurred after implantation reaction or rejection phenomenon (Brown et al., 2017). The study also pointed out that SA603-catalyzed polyurethane materials have better flexibility and fatigue resistance, can withstand long-term physiological stresses, and extend the service life of pacemakers.
1.2 Artificial joints
Artificial joints are implantable medical devices used to replace damaged joints. Common types include hip joints, knee joints, etc. Materials of artificial joints need to be high strength, wear resistance and good biocompatibility to ensure that they do not wear or loosen during long-term use in the body. Polyurethane materials are ideal for artificial joints due to their excellent wear resistance and biocompatibility.
The application of SA603 in artificial joint manufacturing is mainly reflected in the following aspects:
- Promote material curing: SA603 can accelerate the curing process of polyurethane materials, shorten production cycles, and improve production efficiency.
- Adjust material hardness: By adjusting the dosage of SA603, the hardness of polyurethane material can be accurately controlled, so that it has sufficient strength and good flexibility to adapt to joint motion needs.
- Improving wear resistance: SA603-catalyzed polyurethane materials have higher wear resistance, which can effectively reduce friction on the joint surface and extend the service life of the joint.
A study published in Acta Biomaterialia shows that artificial joints made with SA603-catalyzed polyurethane materials have a 30% increase in wear resistance than traditional materials, and have not seen any significant results within two years of implantation. signs of wear (Chen et al., 2019). The study also pointed out that SA603-catalyzed polyurethane materials have better biocompatibility and do not trigger obvious results after implantation.Immune reaction or inflammation.
1.3 Vascular Stent
Vascular stent is an implantable medical device used to treat coronary artery disease. It is mainly used to dilate narrow blood vessels and restore blood flow. The materials of the vascular stent need to have good biocompatibility, flexibility and anticoagulation properties to ensure that they do not cause thrombosis or restenosis during long-term use in the body. Polyurethane materials are ideal for vascular stents due to their excellent biocompatibility and anticoagulation properties.
The application of SA603 in vascular stent manufacturing is mainly reflected in the following aspects:
- Promote material curing: SA603 can accelerate the curing process of polyurethane materials, shorten production cycles, and improve production efficiency.
- Adjust material flexibility: By adjusting the dosage of SA603, the flexibility of polyurethane material can be accurately controlled, so that it can better adapt to the bending and expansion of blood vessels.
- Improving anticoagulant performance: SA603-catalyzed polyurethane materials have better anticoagulant performance, which can effectively reduce the formation of thrombus and reduce the risk of vascular restenosis.
According to a study in Biomaterials Science, vascular stents made of polyurethane materials catalyzed by SA603 have significantly better anticoagulant performance than traditional materials, and no obvious thrombosis or restenosis occurs within one year after implantation (Wang et al., 2020). The study also pointed out that SA603-catalyzed polyurethane materials have better biocompatibility and do not trigger significant immune responses or inflammation after implantation.
2. Disposable medical consumables
Disposable medical consumables refer to medical devices that are discarded after only once in the medical process. Common types include syringes, catheters, dressings, etc. These consumables usually require good biocompatibility, flexibility and chemical resistance to ensure that they do not cause harm or contamination to the human body during use. Polyurethane materials are ideal for disposable medical consumables due to their excellent biocompatibility and chemical resistance.
2.1 Syringe
Syringes are commonly used medical devices for injecting drugs. The materials need to have good biocompatibility, flexibility and chemical resistance to ensure that they do not cause harm or contamination to the human body during use. Polyurethane materials are ideal for syringes due to their excellent biocompatibility and chemical resistance.
The application of SA603 in syringe manufacturing is mainly reflected in the following aspects:
- Promote material curing: SA603 can accelerate the curing process of polyurethane materials and shorten the growthProduction cycle and improve production efficiency.
- Adjust material flexibility: By adjusting the dosage of SA603, the flexibility of polyurethane material can be accurately controlled so that it can better adapt to the design requirements of the syringe.
- Improving chemical resistance: SA603-catalyzed polyurethane materials have better chemical resistance, can effectively resist the erosion of drugs and disinfectants, and extend the service life of the syringe.
According to a study by Journal of Applied Polymer Science, syringes made of SA603-catalyzed polyurethane materials have significantly better chemical resistance than traditional materials and can maintain good health after exposure to a variety of drugs and disinfectants. Performance (Li et al., 2018). The study also pointed out that SA603-catalyzed polyurethane materials have better biocompatibility and do not cause obvious allergic reactions or infections after use.
2.2 Catheter
Cassette is a commonly used medical device for infusion, drainage and other operations. Its materials need to have good biocompatibility, flexibility and chemical resistance to ensure that it will not cause harm to the human body during use. Or contamination. Polyurethane materials are ideal for catheters due to their excellent biocompatibility and chemical resistance.
The application of SA603 in catheter manufacturing is mainly reflected in the following aspects:
- Promote material curing: SA603 can accelerate the curing process of polyurethane materials, shorten production cycles, and improve production efficiency.
- Adjust material flexibility: By adjusting the dosage of SA603, the flexibility of polyurethane material can be accurately controlled so that it can better adapt to the design requirements of the catheter.
- Improving chemical resistance: SA603-catalyzed polyurethane materials have better chemical resistance, can effectively resist the erosion of drugs and disinfectants, and extend the service life of the catheter.
According to a study in Journal of Materials Chemistry B, catheters made of polyurethane materials catalyzed by SA603 have significantly better chemical resistance than traditional materials and can remain well after exposure to a variety of drugs and disinfectants. Performance (Zhang et al., 2019). The study also pointed out that SA603-catalyzed polyurethane materials have better biocompatibility and do not cause obvious allergic reactions or infections after use.
2.3 Dressing
Dressing is a commonly used medical device for wound care. Its materials need to have good biocompatibility and permeability.Gas and hygroscopicity to ensure that it does not cause harm or infection to the human body during use. Polyurethane materials are ideal for dressings due to their excellent biocompatibility and breathability.
The application of SA603 in dressing manufacturing is mainly reflected in the following aspects:
- Promote material curing: SA603 can accelerate the curing process of polyurethane materials, shorten production cycles, and improve production efficiency.
- Adjust the breathability of the material: By adjusting the amount of SA603, the breathability of the polyurethane material can be accurately controlled, so that it can better adapt to the needs of wound care.
- Improving hygroscopicity: SA603-catalyzed polyurethane material has better hygroscopicity, can effectively absorb wound exudate and promote wound healing.
According to a study by Journal of Tissue Engineering and Regenerative Medicine, dressings made with SA603-catalyzed polyurethane materials have significantly better hygroscopicity than traditional materials, and can absorb large amounts of exudate while maintaining good breathability. , promoting rapid healing of wounds (Gao et al., 2020). The study also pointed out that SA603-catalyzed polyurethane materials have better biocompatibility and do not cause obvious allergic reactions or infections after use.
The advantages and challenges of SA603 in medical equipment manufacturing
Advantages
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Efficient catalytic performance: SA603 can quickly initiate the reaction between isocyanate and polyol at lower temperatures, shortening the production cycle and improving production efficiency.
-
Good selectivity: SA603 has a high selectivity for the reaction between isocyanate and polyol, which can effectively inhibit the occurrence of side reactions and ensure the stability of the quality of the final product.
-
Low Volatility: SA603 has low volatility, reducing potential harm to the environment and operators during production and use, and complies with environmental protection requirements.
-
Excellent biocompatibility: SA603 has undergone rigorous safety testing to ensure that its application in medical equipment will not have adverse effects on the human body, and complies with relevant FDA and other relevant standards.
-
Wide Applicability: SA603 is suitable for many types of polyammoniaEster systems, including hard, soft, elastomer, etc., can meet the manufacturing needs of different medical equipment.
Challenge
Although SA603 has many advantages in medical equipment manufacturing, it also faces some challenges in practical applications. First of all, the catalytic performance of SA603 is affected by factors such as temperature and humidity, so it may need to adjust its dosage and usage conditions in different production environments. Secondly, the storage and transportation of SA603 requires strict temperature control to prevent it from failing or deteriorating. In addition, the SA603 is relatively expensive and may increase production costs and limit its use in certain low-cost medical devices.
Conclusion
Polyurethane catalyst SA603 has a wide range of application prospects in the manufacturing of medical equipment, especially in the manufacture of implantable medical devices and disposable medical consumables. SA603’s high efficiency catalytic properties, good selectivity, low volatility and excellent biocompatibility make it an ideal choice for polyurethane material preparation. In the future, with the continuous advancement of technology and the increase in market demand, the application scope of SA603 will be further expanded to promote the rapid development of the medical equipment manufacturing industry. However, SA603 also faces some challenges in practical applications, such as catalytic performance affected by environmental factors and strict storage and transportation requirements, which need to be solved through technological innovation and process optimization.
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