TY - JOUR
T1 - Improving the performance of narrow-bore HPLC columns using active flow technology
AU - Soliven, Arianne
AU - Foley, Dominic
AU - Pereira, Luisa
AU - Hua, Stanly
AU - Edge, Tony
AU - Ritchie, Harald
AU - Dennis, Gary R.
AU - Shalliker, R. Andrew
PY - 2014
Y1 - 2014
N2 - Active flow technology (AFT) columns are designed to remove inefficient flow processes associated with the column wall and radial heterogeneity. This study is the first to explore AFT on a 2.1. mm internal diameter (i.d.) column, emulating a 1.0. mm i.d. column. The performance of the AFT column was compared to a conventional 1.0. mm i.d. column; at the highest linear velocities tested it was observed that the AFT column functioning as a virtual 1.0. mm i.d. column had an efficiency gain that was 58% compared to the conventional 1. mm i.d. column. The performance of the AFT column was also compared to a conventional column of the same physical dimensions and smaller particles; at the highest velocity tested for the conventional 3. μm column, the AFT virtual 1.0. mm i.d. column had a 20% efficiency with half of the backpressure. These comparative gains in efficiency at high flow rates demonstrate the advantage of using AFT 2.1. mm i.d. columns with a virtual 1. mm i.d., for high throughput analyses and low volume detection methods; additionally, a sensitivity gain of 45% was observed.
AB - Active flow technology (AFT) columns are designed to remove inefficient flow processes associated with the column wall and radial heterogeneity. This study is the first to explore AFT on a 2.1. mm internal diameter (i.d.) column, emulating a 1.0. mm i.d. column. The performance of the AFT column was compared to a conventional 1.0. mm i.d. column; at the highest linear velocities tested it was observed that the AFT column functioning as a virtual 1.0. mm i.d. column had an efficiency gain that was 58% compared to the conventional 1. mm i.d. column. The performance of the AFT column was also compared to a conventional column of the same physical dimensions and smaller particles; at the highest velocity tested for the conventional 3. μm column, the AFT virtual 1.0. mm i.d. column had a 20% efficiency with half of the backpressure. These comparative gains in efficiency at high flow rates demonstrate the advantage of using AFT 2.1. mm i.d. columns with a virtual 1. mm i.d., for high throughput analyses and low volume detection methods; additionally, a sensitivity gain of 45% was observed.
UR - http://handle.uws.edu.au:8081/1959.7/548162
U2 - 10.1016/j.microc.2014.05.006
DO - 10.1016/j.microc.2014.05.006
M3 - Article
SN - 0026-265X
VL - 116
SP - 230
EP - 234
JO - Microchemical Journal
JF - Microchemical Journal
ER -