P-Xylene-bis-pyridinium bromide | 14208-10-7

P-Xylene-bis-pyridinium bromide, a quaternary ammonium compound found in scientific research and industry, boasts a diverse range of applications.

Antimicrobial Agent: Widely recognized for its robust antimicrobial properties, P-Xylene-bis-pyridinium bromide serves as a potent disinfectant and antiseptic. Its broad-spectrum efficacy against bacteria, viruses, and fungi positions it as a versatile tool in healthcare and laboratory environments. This compound plays a crucial role in upholding sterile conditions and curbing the transmission of infectious agents, safeguarding both patients and research integrity.

Biochemical Research: Within the realm of biochemical research, P-Xylene-bis-pyridinium bromide emerges as a valuable reagent for probing membrane structure and function. Its utility extends to experiments requiring membrane disruption for intracellular component isolation, facilitating a spectrum of cellular and molecular inquiries such as protein extraction and enzyme assays. This versatile application aids in unraveling the intricacies of cellular biology and biochemistry.

Surface Sanitization: Leveraging its potent disinfectant attributes, P-Xylene-bis-pyridinium bromide finds widespread use in surface sanitization across industries like food processing, pharmaceuticals, and biotechnology. By ensuring equipment and workspaces remain free of microbial contaminants, this compound plays a pivotal role in upholding product safety and maintaining quality standards in manufacturing settings. Its contribution to hygiene and contamination control is paramount in regulated environments.

Chemical Synthesis: In the realm of chemical synthesis, P-Xylene-bis-pyridinium bromide shines as a versatile phase-transfer catalyst, boosting reactivity in select reactions by facilitating reactant transfer between immiscible phases. This unique property enhances the efficiency and yields of various organic synthesis procedures, making it a valuable asset in the laboratory. Its role in catalyzing chemical transformations underscores its significance in driving innovation and advancement in synthetic chemistry.