High Performance Liquid Phase Separations (HPLPS) is a field of analytical chemistry focused on developing advanced liquid-based separation techniques with high resolution, efficiency, and sensitivity. HPLPS encompasses various separation methods such as high performance liquid chromatography (HPLC), ultra-high performance liquid chromatography (UHPLC), and capillary electrophoresis (CE). These techniques rely on the interactions between sample components and stationary/mobile phases to achieve separation. HPLPS is widely used in pharmaceuticals, environmental analysis, food and beverage, clinical diagnostics, and research for analyzing complex mixtures, identifying compounds, and quantifying analytes. HPLPS techniques offer advantages such as rapid analysis times, high throughput, and compatibility with a wide range of sample types. Advances in column technology, instrumentation, and detection systems have significantly improved the performance and capabilities of HPLPS techniques. The development of miniaturized and portable HPLPS systems enables on-site and point-of-care analysis. HPLPS methods are continuously refined to enhance selectivity, sensitivity, and reproducibility, enabling the analysis of trace-level compounds and complex sample matrices. Collaboration between researchers, industry professionals, and regulatory agencies drives innovation and adoption of HPLPS techniques in various scientific disciplines.
Title : Eliminating implant failure in humans with nano chemistry: 30,000 cases and counting
Thomas J Webster, Brown University, United States
Title : Synthesis of chitosan composite of metal organic framework for the adsorption of dyes, kinetic and thermodynamic approach
Tooba Saeed, University of Peshawar, Pakistan
Title : Synthesis, ADMET, PASS, molecular docking, and dynamics simulation investigation of novel octanoyl glucoopyranosides & valeroyl ribofuranoside esters.
Hasinul Babu, University of Chittagong, Bangladesh
Title : Expanding and improve the 2D periodic law of Менделееь elements, and construct the "3D periodic law of elements"
Zhongsheng Lee, Zhengzhou Commercial Technician College, China
Title : Advances in Plasma-Based Radioactive Waste Treatment
Hossam A Gabbar, Ontario Tech University, Canada
Title : Nature meets innovation: Green synthesis of nanoparticles using plant extracts and ionic liquids for a sustainable future
Azeez A Barzinjy, Soran University, Iraq