K. Broeckhoven, D. Cabooter, G. Desmet. Kinetic performance comparison of fully and superficially porous particles with sizes ranging between 2.7 lm and 5 lm:Intrinsic evaluation and application to a pharmaceutical test compound[J]. Journal of Pharmaceutical Analysis, 2013, (5): 313-323.
Citation:
K. Broeckhoven, D. Cabooter, G. Desmet. Kinetic performance comparison of fully and superficially porous particles with sizes ranging between 2.7 lm and 5 lm:Intrinsic evaluation and application to a pharmaceutical test compound[J]. Journal of Pharmaceutical Analysis, 2013, (5): 313-323.
K. Broeckhoven, D. Cabooter, G. Desmet. Kinetic performance comparison of fully and superficially porous particles with sizes ranging between 2.7 lm and 5 lm:Intrinsic evaluation and application to a pharmaceutical test compound[J]. Journal of Pharmaceutical Analysis, 2013, (5): 313-323.
Citation:
K. Broeckhoven, D. Cabooter, G. Desmet. Kinetic performance comparison of fully and superficially porous particles with sizes ranging between 2.7 lm and 5 lm:Intrinsic evaluation and application to a pharmaceutical test compound[J]. Journal of Pharmaceutical Analysis, 2013, (5): 313-323.
Kinetic performance comparison of fully and superficially porous particles with sizes ranging between 2.7 lm and 5 lm:Intrinsic evaluation and application to a pharmaceutical test compound
The reintroduction of superficially porous particles has resulted in a leap forward for the separation performance in liquid chromatography. The underlying reasons for the higher efficiency of columns packed with these particles are discussed. The performance of the newly introduced 5 mm superficially porous particles is evaluated and compared to 2.7 mm superficially porous and 3.5 and 5 mm fully porous columns using typical test compounds (alkylphenones) and a relevant pharmaceutical compound (impurity of amoxicillin). The 5 mm superficially porous particles provide a superior kinetic performance compared to both the 3.5 and 5 mm fully porous particles over the entire relevant range of separation conditions. The performance of the superficially porous particles, however, appears to depend strongly on retention and analyte properties, emphasizing the importance of comparing different columns under realistic conditions (high enough k) and using the compound of interest.