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Items 11551-11600 of 13502

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  1. Biochemical Assay Reagent

    Fe(III)(TDCPP) chloride acts as a biochemical assay reagent, facilitating various life science research applications. This compound serves as a source of iron (III) ions, which are essential for several biological processes. Its use in biochemical assays can aid in the study of enzyme activity and metabolic pathways, contributing valuable insights into cellular functions and interactions.
  2. Metal-organic Framework

    4,4'-(Benzo[c][1,2,5]thiadiazole-4,7-diyl)dibenzoic acid is a vital ligand in the formation of metal-organic frameworks (MOFs). This compound effectively coordinates with metal ions to create robust and versatile architectures, which exhibit potential in gas storage, separation, and sensing applications. Researchers utilize this ligand to explore innovative materials for advanced catalytic processes and environmental remediation solutions.
  3. Metal-organic Framework

    ZIF-9(Co) is a metal-organic framework (MOF) that incorporates cobalt(II) ions with benzimidazole ligands in a 2:1 ratio. This compound exhibits significant porosity and stability, making it suitable for various applications in gas storage, separation, and catalysis. Additionally, ZIF-9(Co) has potential use in drug delivery systems and as a platform for biomolecule immobilization in biochemical research.
  4. Metal-organic Framework

    5-Fluoroisophthalic acid acts as a building block for the synthesis of metal-organic frameworks (MOFs). It is characterized by its ability to coordinate with metal ions, facilitating the formation of highly porous structures. This compound has applications in gas storage, catalysis, and environmental remediation research, making it a valuable tool for advancing materials science.
  5. Metal-organic Framework

    2-Fluorobenzene-1,3,5-tricarboxylic acid acts as a key ligand for the synthesis of metal-organic frameworks (MOFs). Its structural features facilitate coordination with metal ions, promoting the formation of stable and porous networks. This compound is valuable in materials science research, particularly in the development of MOFs for applications such as gas storage, catalysis, and selective adsorption.
  6. Metal-organic Framework

    4,4'-Sulfonyldibenzoic acid is a key component used in the synthesis of metal-organic frameworks (MOFs). This compound serves as a versatile linker, facilitating the formation of stable and high-performance MOF structures. Its unique chemical properties enable applications in gas storage, separation processes, and catalysis, making it valuable for researchers exploring advanced materials in chemical science.
  7. Metal-organic Framework

    Tris(4-(pyridin-4-yl)phenyl)amine serves as a key component in the formation of metal-organic frameworks (MOFs). This compound exhibits significant potential in catalysis, gas adsorption, and sensing applications due to its structural versatility and functional properties. Research into its use in MOFs can further enhance the efficiency of materials for energy storage and environmental remediation.
  8. Metal-organic Framework

    1,3,5-Tri(pyridin-3-yl)benzene serves as a key ligand in the development of metal-organic frameworks (MOFs). This compound exhibits strong coordination properties, facilitating the construction of highly porous and stable frameworks. Its unique structural characteristics make it suitable for applications in gas storage, separation technologies, and catalysis research.
  9. Metal-organic Framework

    1-Methyl-4,4'-bipyridinium chloride is a key component utilized in the formation of metal-organic frameworks (MOFs). This compound serves to enhance the stability and functionality of MOFs in various applications such as gas storage, catalysis, and separation processes. Its unique structural properties make it valuable for researchers investigating material science and nanotechnology.
  10. Metal-organic Framework

    5-Chloro-1,10-phenanthroline primarily targets the coordination chemistry associated with metal-organic frameworks (MOFs). This compound serves as a versatile ligand for various metal ions, facilitating the formation of structurally diverse MOFs. It is utilized in research applications focusing on gas storage, catalysis, and sensor development, leveraging its properties for enhanced material performance and functionality in advanced chemical systems.
  11. Metal-organic Framework

    (Methanetetrayltetrakis(benzene-4,1-diyl))tetrakis(phosphonic acid) serves as a versatile building block for the synthesis of metal-organic frameworks (MOFs). This compound exhibits strong coordination capabilities with metal ions, facilitating the formation of porous structures ideal for gas adsorption and separation applications. Its unique phosphonic acid groups enhance stability and functionality, making it valuable for research in catalysis, environmental remediation, and materials science.
  12. Metal-organic Framework

    2,5-Bis(trifluoromethyl)terephthalic acid serves as a ligand in the formation of metal-organic frameworks (MOFs). This compound possesses significant potential for the development of porous materials with enhanced chemical stability and tailored adsorption properties. Its applications include gas storage, catalysis, and separation processes in various fields of chemical and materials research. The incorporation of trifluoromethyl groups enhances the electronic characteristics, making it a valuable component for innovative MOF design.
  13. Metal-organic Framework

    2,6-Dimethylterephthalic acid serves as a key building block in the synthesis of metal-organic frameworks (MOFs). This compound facilitates the formation of porous structures with tunable properties, making it valuable for applications such as gas storage, catalysis, and environmental remediation. Its structural features allow for the incorporation of various metal ions, enhancing the performance of the resulting MOF materials in various research endeavors.
  14. Metal-organic Framework

    3,6-Di(pyridin-3-yl)-1,2,4,5-tetrazine is a metal-organic framework (MOF) known for its exceptional ligand properties. It exhibits significant interactions with metal ions, facilitating the formation of stable and structured frameworks. This compound is widely utilized in research applications aimed at developing advanced materials for gas storage, catalysis, and sensing technologies. Its unique structure makes it a valuable tool for exploring metal coordination and enhancing material functionalities.
  15. Metal-organic Framework

    2,5-Di(pyridin-2-yl)-1H-pyrrole is a metal-organic framework (MOF) compound designed for applications in materials science and catalysis. This compound exhibits strong coordination properties, making it suitable for the development of advanced materials and sensing applications. Its unique structural attributes facilitate the incorporation of metal ions, allowing for enhanced stability and functionality in various chemical reactions.
  16. Metal-organic Framework

    1,3-Bis(2,4,6-trimethylphenyl)-1,3-dihydro-2H-imidazol-2-ylidene acts as a metal-organic framework (MOF) facilitator. This compound exhibits excellent coordination properties, making it an effective ligand for metal ions and enhancing catalytic activity in various reactions. Its applications span across materials science, catalysis, and gas storage, providing valuable insights into the design and development of functionalized MOFs for advanced research.
  17. Metal-organic Framework

    1,2,4,5-Tetra(pyridin-3-yl)benzene is a ligand designed for the synthesis of metal-organic frameworks (MOFs). This compound exhibits strong coordination properties due to the presence of pyridine functionalities, making it ideal for forming stable frameworks with various metal ions. It has important applications in fields such as gas storage, separation processes, and catalysis, facilitating advancements in materials science and chemical engineering research.
  18. Metal-organic Framework

    4,4'-Azobispyridine is a versatile ligand used in the synthesis of metal-organic frameworks (MOFs). It can coordinate with various metal ions, facilitating the construction of porous materials with tunable properties. Due to its structural and functional attributes, 4,4'-Azobispyridine is valuable in studies related to gas storage, catalysis, and molecular separation. Its ability to exhibit switchable properties makes it an intriguing candidate for applications in advanced materials research.
  19. Metal-organic Framework

    [1,1'-Biphenyl]-3,3',4,4'-tetracarboxylic acid serves as a key ligand in the formation of metal-organic frameworks (MOFs). This compound possesses multiple carboxylic acid functional groups, facilitating coordination with metal ions to create stable network structures. Its unique properties make it suitable for applications in gas storage, catalysis, and sensing technologies. Researchers utilize this ligand to investigate the synthesis and characterization of novel MOFs with tailored functionalities.
  20. Metal-organic Framework

    6-(2,3,3-Trimethyl-3H-indol-1-ium-1-yl)hexanoate hydrobromide functions as a metal-organic framework (MOF). This compound exhibits significant structural properties conducive to gas adsorption and separation applications. It serves as a valuable reagent for studies aimed at developing advanced materials for catalysis and environmental remediation. Researchers can leverage its unique qualities in various fields, including materials science and chemical engineering.
  21. Metal-organic Framework

    3,4-Pyridinedicarboxylic acid, also known as cinchomeronic acid, serves as a key building block for the synthesis of metal-organic frameworks (MOFs). This compound can coordinate with various metal ions, facilitating the formation of porous structures with tunable properties. Research applications include catalysis, gas storage, and drug delivery, making it an important reagent in the fields of material science and nanotechnology.
  22. Metal-organic Framework

    [1,1'-Biphenyl]-3,4',5-tricarboxylic acid primarily functions as a ligand in the synthesis of metal-organic frameworks (MOFs). Its unique structure facilitates the coordination of metal ions, resulting in the formation of porous materials with potential applications in gas storage, separation, and catalysis. This compound is essential for researchers developing new MOFs with tailored properties for advanced material science applications.
  23. Ester Product

    1-Docosahexaenoyl-sn-glycero-3-phosphocholine is a phospholipid ester that plays a critical role in cellular membrane dynamics. This compound is known for its ability to modulate membrane fluidity and lipid signaling pathways. It is widely used in research applications focused on studying membrane properties, lipid metabolism, and cellular signaling processes, making it an essential reagent for investigations in biochemistry and cell biology.
  24. Metal-organic Framework

    2,4,6-Tri([1,1'-biphenyl]-4-yl)-1,3,5-triazine functions as a ligand in the formation of metal-organic frameworks (MOFs). This compound exhibits excellent coordination properties, enabling the construction of robust and functionalized MOF structures. It is utilized in various research applications, including gas storage, catalysis, and material sciences, due to its structural versatility and stability. The incorporation of this triazine-based ligand can enhance the performance and properties of resultant MOFs for advanced scientific studies.
  25. Ester Product

    10-Oxo-12(Z)-octadecenoic acid is an ester product that functions as a bioactive lipid mediator. It plays a crucial role in various biological processes, including inflammation and metabolic regulation. This compound is valuable for research applications focused on lipid biology, cellular signaling pathways, and metabolic disorders. Its bioactivity makes it a useful tool for investigating the role of oxylipins in health and disease.
  26. Metal-organic Framework

    1,2,4-Benzenetricarboxylic acid, also known as Trimellitic Acid, serves as a vital building block for metal-organic frameworks (MOFs). Its carboxylic acid groups facilitate the coordination with metal ions, enabling the formation of stable and porous structures. This compound is widely used in research applications including gas storage, separation processes, and catalysis, making it essential in material science and nanotechnology studies.
  27. Metal-organic Framework

    2,5-Diaminobenzoic acid serves as a building block for metal-organic frameworks (MOFs). Its structural properties enable the formation of stable MOFs, which are utilized in a variety of applications including gas storage, catalysis, and drug delivery. This compound facilitates the development of advanced materials and is essential in the study of porous structures for biomedical and environmental applications.
  28. Drug Impurity

    Atenolol impurity 8 is a structural impurity associated with Atenolol, a selective beta-1 adrenergic receptor blocker. This compound is crucial for analyzing the purity of Atenolol formulations and evaluating potential impacts on drug efficacy and safety. It serves as an important reference standard in the pharmaceutical industry for quality control and compliance in drug development and analysis.
  29. Drug Impurity

    Ranolazine impurity 3 is a chemical impurity associated with Ranolazine, primarily used as a reference standard in analytical and quality control applications. This compound is essential for ensuring the purity and consistency of Ranolazine formulations. Its characterization contributes to the understanding of metabolic pathways and the identification of potential degradation products. Research involving this impurity aids in enhancing the quality of pharmaceutical formulations and supports regulatory compliance in drug development processes.
  30. Drug Impurity

    Olmesartan impurity 1 serves as a structural impurity related to the antihypertensive agent Olmesartan. This compound is essential for the analytical characterization of Olmesartan, particularly in the context of quality control and regulatory compliance in pharmaceutical development. Its presence and quantification can provide insights into the synthesis purity and stability profiles of Olmesartan formulations.
  31. Drug Impurity

    Rivaroxaban impurity 67 is a defined impurity of the anticoagulant Rivaroxaban. This compound serves as a critical reference standard for analytical and quality control processes in the pharmaceutical industry. It aids in routine testing, stability analysis, and ensuring the purity of Rivaroxaban formulations in drug development and regulatory compliance.
  32. Drug Impurity

    Cabozantinib impurity 7 is a synthetic impurity derivative of the tyrosine kinase inhibitor Cabozantinib. It serves as a crucial reference standard for quality control and analytical studies related to Cabozantinib production. This compound aids in the characterization and assessment of drug purity, essential for pharmacokinetics and toxicological research applications.
  33. Drug Impurity

    Estradiol impurity 1 is a known impurity associated with the synthesis of Estradiol. This compound can serve as a critical reference for assessing the purity of Estradiol formulations in research and quality control applications. It is important for researchers studying the metabolism and pharmacokinetics of estrogenic compounds, as well as in the evaluation of drug safety and efficacy.
  34. Drug Intermediate

    (1R,3S)-3-Hydroxycyclopentane carboxylic acid methyl ester serves as a valuable synthetic intermediate in pharmaceutical synthesis. This compound can facilitate the development of bioactive molecules and various drug formulations. Its unique structure aids in the exploration of novel therapeutic agents, making it an essential reagent for research in medicinal chemistry.
  35. Drug Impurity

    Lifitegrast impurity 4 hydrochloride is a chemical impurity associated with Lifitegrast, primarily known for its role as a lymphocyte function-associated antigen-1 (LFA-1) antagonist. This impurity serves as a reference standard for analytical characterization and quality control in pharmacological studies of Lifitegrast. Research applications include assessing the purity of the active pharmaceutical ingredient and evaluating potential effects on drug efficacy and safety profiles.
  36. Drug Impurity

    Sitagliptin impurity 25 is a known impurity associated with the DPP-4 inhibitor Sitagliptin, primarily targeting the Dipeptidyl Peptidase-4 enzyme. This compound is essential for quality control in the synthesis and analysis of Sitagliptin and is relevant for pharmacokinetic and toxicological studies. Its characterization supports research into drug formulation and regulatory compliance.
  37. Drug Impurity

    Tamsulosin Impurity 6 serves as a drug impurity associated with the pharmaceutical compound tamsulosin. Its presence is critical for quality control and regulatory compliance during the manufacturing process. This compound is utilized in research applications to investigate the safety and efficacy of tamsulosin formulations, contributing to the understanding of potential impacts on drug performance and stability.
  38. Drug Impurity

    Donepezil impurity 10 is a known impurity associated with the compound Donepezil, a reversible inhibitor of the enzyme acetylcholinesterase. This reagent is significant for analytical studies aimed at monitoring the purity of Donepezil in pharmaceutical formulations. It serves as a reference standard in quality control processes and method development, ensuring compliance with regulatory guidelines in drug manufacturing and research applications.
  39. Drug Impurity

    Apixaban 4,5-dehydro carboxylic acid is a known drug impurity of Apixaban, an anticoagulant that functions primarily by inhibiting Factor Xa in the coagulation cascade. This compound serves as an important reference standard for analytical and stability studies in pharmaceutical development. Research applications include the assessment of drug purity, identification of degradation products, and evaluation of manufacturing processes.
  40. Drug Impurity

    Tamsulosin impurity 21 is a chemical impurity associated with the drug Tamsulosin, which primarily targets the α1-adrenergic receptors. This impurity may serve as a valuable reference standard in the analysis of Tamsulosin formulations. Its identification is crucial for assessing the purity and quality of pharmaceutical products in drug development and quality control.
  41. Drug Impurity

    Ramipril impurity 3 is a minor impurity associated with the angiotensin-converting enzyme (ACE) inhibitor Ramipril. This compound serves as a reference standard in the analysis of Ramipril for quality control and pharmaceutical research applications. Investigating impurities like Ramipril impurity 3 is essential for understanding the compound's safety profile and ensuring compliance with regulatory standards.
  42. Drug Impurity

    Terbinafine impurity 13 is a known impurity associated with the antifungal agent Terbinafine. This compound serves as a reference standard for analytical studies and quality control in pharmaceutical formulations. Its characterization and quantification are essential for ensuring the purity and efficacy of Terbinafine in drug development and regulatory processes.
  43. Drug Impurity

    Vildagliptin impurity 24 is a chemical impurity associated with the antidiabetic agent Vildagliptin. This impurity is crucial for analytical and quality control applications in pharmaceutical research and development. Its identification and quantification are essential for assessing the purity of Vildagliptin and ensuring the safety and efficacy of formulations containing this compound.
  44. Drug Impurity

    Telmisartan impurity 5 (2-Boc-4'-(bromomethyl)biphenyl) is a characterized impurity associated with Telmisartan, an antihypertensive agent. It serves as a reference standard for quality control and analytical testing in pharmaceutical development. The presence and quantification of this impurity are crucial for assessing the purity and safety profiles of Telmisartan formulations.
  45. Drug Impurity

    Escitalopram impurity 7 oxalate, also known as 3-Hydroxy citalopram oxalate, is a drug impurity associated with Escitalopram oxalate. This compound is utilized in pharmaceutical research and development to assess the purity and stability of escitalopram formulations. Its analysis is critical for ensuring compliance with regulatory standards and understanding the pharmacokinetic profile of the parent drug.
  46. Drug Impurity

    Sitagliptin impurity 1 is a known impurity associated with the drug Sitagliptin, an inhibitor of the Dipeptidyl Peptidase-4 (DPP-4) enzyme. This compound is utilized primarily for quality control and analytical purposes in pharmaceutical research, ensuring the purity and safety of Sitagliptin formulations. It plays a critical role in the development and validation of quality assurance protocols in drug manufacturing.
  47. Drug Impurity

    Montelukast impurity 14 is a chemical compound associated with the synthesis of Montelukast, specifically categorized as a drug impurity. This impurity can be used in analytical chemistry to assess the purity of Montelukast formulations and contribute to quality control processes. Its detection and quantification are essential for ensuring compliance with regulatory standards in pharmaceutical development and manufacturing.
  48. Drug Impurity

    Terbinafine impurity 5 is a chemical impurity associated with the antifungal agent Terbinafine. It is primarily utilized in the analysis of drug formulations and quality control assessments to ensure the purity of pharmaceutical products. This impurity serves as an essential reference standard in stability testing and the development of analytical methods in pharmaceutical research.
  49. Drug Impurity

    Sertraline impurity 5 is a chemical impurity associated with the selective serotonin reuptake inhibitor (SSRI) Sertraline. This compound is utilized primarily in pharmaceutical research for the assessment of drug purity and stability. It serves as a critical reference standard in the analytical evaluation of Sertraline formulations, helping to ensure compliance with regulatory quality standards in drug development.

Items 11551-11600 of 13502

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