Description
Specifications Table
Product Name – BAPTA AM extrapure, 98% Quantity/Pack Size – 10 Mg, 1 Gms Form – Powder Grade – Extrapure, 98% Application – Research and laboratory use
Product Overview
BAPTA AM extrapure, 98% is a high-purity chemical compound widely used in laboratory research and applications. It is a derivative of BAPTA, a calcium chelator, and is known for its ability to bind calcium ions selectively. This product is manufactured to the highest standards, ensuring a purity level of 98%, making it ideal for precise and accurate laboratory work. The extrapure grade guarantees minimal impurities, enhancing the reliability and reproducibility of experimental results. BAPTA AM is commonly used in various research fields, including biochemistry, cell biology, and neuroscience, where calcium signaling plays a crucial role. Its ability to permeate cell membranes and release calcium ions upon hydrolysis makes it a valuable tool for studying intracellular calcium dynamics. The product is supplied in a convenient powder form, making it easy to handle and store. Its high purity and consistent quality make it a trusted choice for researchers and educators seeking reliable laboratory reagents.
FAQs
1. What is the primary application of BAPTA AM extrapure, 98%?
BAPTA AM extrapure, 98% is primarily used as a calcium chelator in laboratory research to study intracellular calcium dynamics.
2. What is the purity level of this product?
The purity level of BAPTA AM extrapure, 98% is 98%, ensuring high-quality and reliable results in laboratory applications.
3. In what form is BAPTA AM extrapure, 98% supplied?
BAPTA AM extrapure, 98% is supplied in a powder form, making it easy to handle and store.
4. What are the typical research fields where BAPTA AM extrapure, 98% is used?
BAPTA AM extrapure, 98% is commonly used in biochemistry, cell biology, and neuroscience research fields.
5. How does BAPTA AM extrapure, 98% permeate cell membranes?
BAPTA AM extrapure, 98% permeates cell membranes and releases calcium ions upon hydrolysis, making it a valuable tool for studying intracellular calcium dynamics.
