Ozone Specialities

Synonym(s):

Fmoc-OSu, FMOC-ONSu, N-(9H-Fluoren-9-ylmethoxycarbonyloxy)succinimide, N-(9-Fluorenylmethoxycarbonyloxy)succinimide, 9-Fluorenylmethyl-succinimidyl carbonate

• Peptide Synthesis: This compound serves as a protecting group for amino acids during peptide synthesis, allowing for the selective modification of amino acids without unwanted reactions.
• Drug Development: It plays a crucial role in the development of pharmaceuticals, particularly in creating compounds that require specific amino acid configurations for enhanced efficacy.
• Biotechnology: In the field of biotechnology, it is used to produce modified proteins that can improve the stability and activity of enzymes and other biological molecules.
• Research in Neuroscience: The compound is utilized in studies related to neurotransmitter pathways, helping researchers understand the role of amino acids in brain function and potential treatments for neurological disorders.
• Material Science: Boc-a-aminoisobutyric acid is also applied in the development of polymers and materials that require specific chemical properties, enhancing their performance in various applications.

• Peptide Synthesis: It serves as a protecting group for amino acids during the synthesis of peptides, allowing for selective reactions without affecting other functional groups.
• Drug Development: In pharmaceutical research, Boc-glycine is used to modify drug candidates, enhancing their stability and bioavailability, which is crucial for developing effective medications.
• Bioconjugation: This compound is employed in bioconjugation techniques to link biomolecules, such as proteins and antibodies, facilitating the creation of targeted therapies and diagnostics.
• Polymer Chemistry: It plays a role in the synthesis of polyamides and other polymers, contributing to materials with specific properties for applications in coatings and adhesives.
• Analytical Chemistry: Boc-glycine is utilized in chromatography and mass spectrometry as a derivatizing agent, improving the detection and analysis of various compounds.

• Synonyms:N-ACETYL-3,5-DIIODO-L-TYROSINE;Levothyroxine Related Compound (N-Acetyl-3,5-Diiodo-L-Tyrosine);(2S)-2-acetamido-3-(4-hydroxy-3,5-diiodophenyl)propanoic acid;2-acetamido-3-(4-hydroxy-3,5-diiodophenyl)propanoic acid;n-acetyl-3-5-diiodo-l-tyrosine1/2h2o*crystallin ;3,5-DIIODO-N-ACETYL-L-TYROSINE;AC-3,5-DIIODO-TYR-OH;N-Acetyl-3,5-Diiodo-L-tyrosine dihydrate

Name:BOC-L-PYROGLUTAMIC ACID BENZYL ESTER

CAS: 113400-36-5

MF:C17H21NO5

MW: 319.35

MP: 69-70 °C

BP:464.9±38.0 °C

Density:1.219

FP: 235.0±26.8 °C

Appearance: White powder

Purity:97%

Applications:amino acid

• Pharmaceutical Development: This compound serves as a building block in the synthesis of various pharmaceuticals, particularly in the development of drugs targeting neurological disorders.
• Protein Engineering: It plays a crucial role in the modification of peptides and proteins, enhancing their stability and functionality, which is essential in biotechnological applications.
• Food Industry: Used as a flavoring agent, it enhances the taste profile of food products, making it valuable for food scientists and manufacturers.
• Cosmetic Formulations: Its properties are leveraged in skincare products, providing moisturizing benefits and improving the texture of formulations.
• Research in Neurobiology: Acetyl-L-phenylalanine is studied for its potential effects on neurotransmitter activity, offering insights into brain function and potential therapeutic avenues.

• Fmoc-Dab(Boc)-OH
• 125238-99-5
• (S)-2-((((9H-Fluoren-9-yl)methoxy)carbonyl)amino)-4-((tert-butoxycarbonyl)amino)butanoic acid
• Fmoc-L-dab(Boc)-OH
• Fmoc-N4-Boc- L-2,4-diaminobutyric acid

• Peptide Synthesis: This compound serves as a key building block in the synthesis of peptides, particularly in the development of bioactive peptides that can be used in pharmaceuticals.
• Drug Development: Its unique structure allows for the modification of drug candidates, enhancing their stability and bioavailability, which is crucial in medicinal chemistry.
• Biomaterials: The compound is used in creating hydrogels and other biomaterials, which are essential in tissue engineering and regenerative medicine.
• Research on Collagen: It plays a significant role in studying collagen stability and structure, providing insights into skin health and wound healing.
• Cosmetic Formulations: Its properties make it beneficial in cosmetic products aimed at improving skin texture and hydration, appealing to the beauty and personal care industry.

• 15761-39-4

• Peptide Synthesis: This compound serves as a protecting group in the synthesis of peptides, allowing for selective reactions without interfering with other functional groups. Its stability under various conditions makes it a preferred choice for chemists.
• Drug Development: In pharmaceuticals, Boc-L-phenylalanine is used to create peptide-based drugs. Its incorporation can enhance the bioactivity and stability of therapeutic peptides, making them more effective in treating diseases.
• Biotechnology: Researchers in biotechnology utilize this compound for the production of modified proteins. By incorporating Boc-L-phenylalanine, scientists can study protein interactions and functions more effectively.
• Analytical Chemistry: It is employed in various analytical techniques, including chromatography, to separate and identify amino acids and peptides. This application is crucial for quality control in food and pharmaceutical industries.
• Research in Neuroscience: The compound is used in studies related to neurotransmitter

• Peptide Synthesis: This compound serves as a key building block in the synthesis of peptides, allowing researchers to create complex structures with specific functionalities, enhancing the development of new therapeutic agents.
• Bioconjugation: It is used in bioconjugation processes, where it helps link biomolecules like proteins and antibodies to other molecules, improving drug delivery systems and diagnostic tools.
• Drug Development: The compound plays a significant role in pharmaceutical research, particularly in the design of prodrugs that enhance the solubility and bioavailability of active pharmaceutical ingredients.
• Protein Modification: Researchers utilize this chemical for selective modification of proteins, which can improve their stability and activity, leading to better therapeutic outcomes.
• Research in Immunology: It aids in the development of immunological assays by facilitating the attachment of antigens to surfaces, thus enhancing the sensitivity and specificity of tests.

• Peptide Synthesis: This compound serves as a key building block in the synthesis of peptides, allowing researchers to create complex proteins for various studies.
• Drug Development: It plays a crucial role in the development of pharmaceuticals, particularly in designing drugs that target specific biological pathways.
• Biotechnology: Used in the production of biopharmaceuticals, it helps in the formulation of therapeutic proteins, enhancing their stability and efficacy.
• Material Science: Its properties are leveraged in creating novel materials, including hydrogels and drug delivery systems, which are essential for advanced medical applications.
• Research in Neuroscience: This compound aids in the synthesis of neurotransmitter analogs, facilitating studies on brain function and neuropharmacology.

Synonym(s):

Fmoc-hArg(Pbf)-OH, N-α-Fmoc-N ^G-(2,2,4,6,7-pentamethyldihydrobenzofuran-5-sulfonyl)-L-homoarginine

Boc-sarcosine is widely utilized in research focused on:

• Peptide Synthesis: It serves as a key building block in the synthesis of peptides, particularly in the development of biologically active compounds and pharmaceuticals.
• Drug Development: Researchers leverage its properties to design and optimize drug candidates, especially in the field of cancer therapeutics, due to its ability to enhance bioavailability.
• Bioconjugation: Boc-sarcosine is used in bioconjugation processes to attach biomolecules to surfaces or other molecules, facilitating targeted drug delivery systems.
• Analytical Chemistry: It acts as a standard in analytical methods, helping in the quantification of amino acids and peptides in various samples.
• Research in Neuroscience: The compound is investigated for its potential effects on neurotransmitter systems, contributing to studies on cognitive function and neuroprotection.

• Pharmaceutical Development: This compound serves as an important intermediate in the synthesis of various pharmaceuticals, particularly those targeting neurological disorders. Its ability to enhance bioavailability makes it a valuable asset in drug formulation.
• Peptide Synthesis: It is commonly used in the production of peptides, which are crucial for developing therapeutic agents. The stability and reactivity of this compound facilitate efficient coupling reactions in peptide synthesis.
• Biochemical Research: Researchers leverage this compound in studies involving amino acid metabolism and protein interactions. Its unique structure allows for the exploration of enzyme activities and metabolic pathways.
• Cosmetic Formulations: The compound is also explored in cosmetic chemistry for its potential skin benefits, such as hydration and anti-aging properties, making it a sought-after ingredient in skincare products.
• Food Industry Applications: It can be utilized as a flavor enhancer or food additive, providing a unique taste profile while being safe for consumption, thus appealing to food scientists and manufacturers.

• Cytidine has a chemical formula of C9H13N3O5 and a molar mass of 243.217 g/mol.
• It consists of a cytosine base linked to a ribose sugar through an N-glycosidic bond.
• Cytidine is a white, crystalline powder that is highly soluble in water.