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• 2. Assessing the effectiveness of microplastic extraction methods on fishmeal with different properties
  Chloe Way,Malcolm D. Hudson,Ian D. Williams,G. John Langley,Robert Marsh Anal. Methods 2022 14 606
• 3. The condensed phosphates
  B. Topley Q. Rev. Chem. Soc. 1949 3 345
• 4. Properties and structural investigation of gallophosphate glasses by 71Ga and 31P nuclear magnetic resonance and vibrational spectroscopies
  Patricia Hee,Randi Christensen,Yannick Ledemi,John E. C. Wren,Marc Dussauze,Thierry Cardinal,Evelyne Fargin,Scott Kroeker,Younès Messaddeq J. Mater. Chem. C 2014 2 7906
• 5. Investigation of enhanced oxidation stability of microencapsulated enzymatically produced tuna oil concentrates using complex coacervation
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Professional Introduction to Sodium Polyphosphate (CAS No. 10361-03-2)

Sodium polyphosphate, a compound with the chemical formula Na₆P₆O₂₁·2H₂O, is a widely utilized inorganic salt in various industrial and pharmaceutical applications. Its CAS number, 10361-03-2, identifies it as a specific chemical entity with distinct properties and uses. This compound, often referred to as sodium polyphosphate, is a linear polymer of sodium and phosphate ions, which contributes to its versatility in multiple fields.

The significance of sodium polyphosphate lies in its multifunctional properties, which make it indispensable in industries ranging from food processing to pharmaceuticals. One of the most notable applications of this compound is in the field of water treatment, where it acts as a sequestrant and pH adjuster. By chelating metal ions, it prevents scale formation and enhances the efficiency of water treatment processes.

In the pharmaceutical sector, sodium polyphosphate is employed as an excipient in drug formulations. Its ability to stabilize active pharmaceutical ingredients (APIs) under varying conditions makes it a preferred choice for formulating tablets, syrups, and other dosage forms. Recent studies have highlighted its role in enhancing drug solubility and bioavailability, which is crucial for improving therapeutic outcomes.

The compound's structural properties also make it suitable for use as a dispersant in paints and coatings. By preventing particle aggregation, sodium polyphosphate ensures uniform distribution of pigments and resins, leading to improved coating performance. This application underscores its importance in the chemical manufacturing industry.

Recent advancements in nanotechnology have opened new avenues for the use of sodium polyphosphate. Researchers have been exploring its potential as a template for synthesizing nanomaterials due to its ability to self-assemble into ordered structures. These nanomaterials have promising applications in drug delivery systems, where precise control over particle size and morphology is essential for targeted therapy.

The environmental impact of using sodium polyphosphate has also been a subject of extensive research. Studies indicate that when properly disposed of, it does not pose significant environmental hazards. However, concerns about its accumulation in water bodies have led to investigations into biodegradable alternatives. This has spurred innovation in developing eco-friendly derivatives that maintain the beneficial properties of sodium polyphosphate while reducing environmental impact.

In the realm of biomedical research, sodium polyphosphate has been studied for its potential role in bone regeneration. Its ability to mimic natural bone minerals has led to experiments involving its incorporation into biomaterials designed for orthopedic applications. Preliminary results suggest that it can enhance bone cell proliferation and mineralization, making it a promising candidate for future treatments.

The compound's role in maintaining optimal pH levels has also been explored in the context of industrial processes. In sectors such as textile manufacturing and paper production, sodium polyphosphate is used to regulate pH during processing stages. This ensures consistent product quality and efficiency in production lines.

The future prospects of sodium polyphosphate are vast, with ongoing research uncovering new applications and refining existing ones. As technology advances, the demand for high-performance materials like sodium polyphosphate is expected to grow exponentially. Its adaptability across multiple industries makes it a cornerstone compound in modern chemistry.

• 37267-86-0(Metaphosphoric Acid, Lump)
• 62533-93-1(Tridecaphosphoric acid, pentadecasodium salt)
• 14550-21-1(Metaphosphoric acid(H6P6O18), sodium salt (1:?))
• 35340-88-6(1,3,5,7,9,11,13,15,17,19-Decaoxa-2,4,6,8,10,12,14,16,18,20-decaphosphacycloeicosane,2,4,6,8,10,12,14,16,18,20-decahydroxy-, 2,4,6,8,10,12,14,16,18,20-decaoxide,sodium salt (1:10))
• 31961-83-8(METAPHOSPHATE)
• 50813-16-6(Sodium polymetaphosphate)
• 15551-60-7(Metaphosphoric acid(HPO3), calcium sodium salt (6:1:4) (8CI,9CI))
• 10343-62-1(Metaphosphoric acid(HPO3) (7CI,8CI,9CI))
• 68915-31-1(Sodium Hexametaphosphate)
• 13566-15-9(Metaphosphoric acid(Zn(PO3)2), zinc salt (2:1))