All-trans-Retinoate, a form of retinoid derived from Vitamin A, has gained considerable attention in the field of skincare and dermatology due to its effectiveness in treating various skin conditions. This compound is praised for its ability to stimulate cell turnover, promote collagen production, and improve skin texture and tone. For individuals seeking to maintain healthy and youthful-looking skin, incorporating products containing all-trans-Retinoate into their skincare routine may prove beneficial in achieving desired results. Its relevance extends beyond the realm of beauty and aesthetics, as it also plays a role in addressing certain dermatological concerns such as acne, hyperpigmentation, and fine lines. As consumers increasingly prioritize self-care and wellness, all-trans-Retinoate represents a valuable ingredient in the quest for healthier, more radiant skin.
Table of Contents:
- 💡 Commercial Applications
- ⚗️ Chemical & Physical Properties
- 🏭 Production & Procurement
- ⚠️ Safety Considerations
- 🔬 Potential Research Directions
- 🧪 Related Compounds
💡 Commercial Applications
All-trans-Retinoate, also known as retinoic acid, is widely utilized in the commercial and industrial sectors. It is a key ingredient in various skincare products, such as anti-aging creams and acne treatments, due to its ability to promote skin cell turnover and increase collagen production. Additionally, all-trans-Retinoate is used in the manufacturing of certain paints and coatings for its properties as a drying agent and UV stabilizer.
In the realm of drug and medication applications, all-trans-Retinoate plays a significant role in dermatology and ophthalmology. It is used in the treatment of conditions like acne, psoriasis, and eczema, as well as certain types of skin cancer. In ophthalmology, all-trans-Retinoate is utilized in the treatment of various eye disorders, including night blindness and dry eye syndrome, due to its role in maintaining healthy vision and eye function.
Furthermore, all-trans-Retinoate has shown promise in the field of regenerative medicine and tissue engineering. Researchers are exploring its potential for promoting wound healing, tissue regeneration, and the development of novel therapeutic approaches for various diseases. With its ability to modulate gene expression and cellular differentiation, all-trans-Retinoate holds great potential for advancing the field of regenerative medicine and improving patient outcomes.
⚗️ Chemical & Physical Properties
All-trans-Retinoate appears as a yellow crystalline solid with little to no odor. It is a chemical compound commonly used in skincare products due to its beneficial effects on skin health.
The molar mass of all-trans-Retinoate is approximately 286.44 g/mol, and its density is around 1.024 g/cm3. Comparatively, common food items such as sugar have a molar mass of 342.3 g/mol and a density of 1.59 g/cm3, indicating that all-trans-Retinoate is lighter and less dense than sugar.
All-trans-Retinoate has a melting point of around 130-131°C and a boiling point of approximately 228-230°C. This is higher than the melting point of common substances like butter (around 32-35°C) but lower than the boiling point of water (100°C), making all-trans-Retinoate relatively stable at elevated temperatures.
All-trans-Retinoate is sparingly soluble in water and exhibits a low viscosity. In comparison, common food items like salt are highly soluble in water, while honey has a higher viscosity. This makes all-trans-Retinoate less readily dissolvable in water and less thick in consistency compared to these food items.
🏭 Production & Procurement
All-trans-Retinoate, a bioactive form of vitamin A, is typically produced through a multi-step chemical synthesis process. The starting materials for this synthesis usually include retinol and other specific reagents to facilitate the transformation into all-trans-Retinoate. This manufacturing process requires skilled chemists and precise control of reaction conditions to ensure high purity and yield.
The procurement of all-trans-Retinoate typically involves sourcing from specialized chemical manufacturers or suppliers. These suppliers may offer the compound in various forms such as powders, solutions, or premixed formulations. Upon procurement, all-trans-Retinoate is commonly transported in sealed containers to prevent degradation or contamination during transit. Proper handling and storage conditions are necessary to maintain the compound’s stability and effectiveness.
In the biomedical and cosmetic industries, all-trans-Retinoate is often obtained through partnerships with contract manufacturers or distributors. These entities play a crucial role in ensuring the timely delivery and quality control of the compound for use in research or product formulations. Depending on the specific application, all-trans-Retinoate may be procured in bulk quantities or customized formulations tailored to the end user’s requirements.
⚠️ Safety Considerations
Safety considerations for all-trans-Retinoate include ensuring proper storage in a cool, dry place away from direct sunlight. It is important to use appropriate personal protective equipment, such as gloves and goggles, when handling this substance to prevent skin and eye irritation. Additionally, it is advisable to work in a well-ventilated area to avoid inhalation of fumes.
Hazard statements for all-trans-Retinoate include causing skin irritation and serious eye damage. It may also be harmful if swallowed or if inhaled. Prolonged or repeated exposure may cause dryness or cracking of the skin.
Precautionary statements for all-trans-Retinoate advise individuals to wear protective gloves, clothing, and eye/face protection when handling this substance. It is important to avoid breathing in dust/fume/gas/mist/vapors/spray. In case of skin irritation or rash, immediately wash affected areas with water and seek medical advice. If inhaled, move to fresh air and seek medical attention if experiencing respiratory discomfort.
🔬 Potential Research Directions
Research on all-trans-Retinoate may delve into its potential role in skin aging and rejuvenation, as well as its effects on gene expression related to collagen production and skin health.
Studies could investigate the use of all-trans-Retinoate in topical skincare formulations, exploring its stability, efficacy, and potential side effects, to optimize its benefits in skincare products.
Further research may examine the biological mechanisms by which all-trans-Retinoate functions at the cellular level, shedding light on its molecular targets and signaling pathways to better understand its therapeutic potential.
🧪 Related Compounds
One similar compound to all-trans-Retinoate based upon molecular structure is 13-cis-Retinoic acid. This compound is an isomer of all-trans-Retinoate, with a similar structure but a different arrangement of atoms. 13-cis-Retinoic acid is also a biologically active form of vitamin A and is commonly used in the treatment of acne and other skin conditions.
Another compound that is structurally similar to all-trans-Retinoate is 9-cis-Retinoic acid. Like 13-cis-Retinoic acid, 9-cis-Retinoic acid is an isomer of all-trans-Retinoate with a different arrangement of atoms. This compound is also biologically active and is known to regulate gene expression and cell differentiation in the body.
A third compound with a molecular structure similar to all-trans-Retinoate is Adapalene. Adapalene is a synthetic retinoid that shares some structural similarities with vitamin A derivatives like all-trans-Retinoate. This compound is commonly used in the treatment of acne and other skin conditions, similar to other retinoids.
