Tags

Type your tag names separated by a space and hit enter

Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry.
Pharm Res. 2017 06; 34(6):1330-1337.PR

Abstract

PURPOSE

The hydrodynamics in USP dissolution apparatus 3, at five different dip rates, was characterized by analyzing phase-averaged velocity fields obtained using Particle Image Velocimetry (PIV).

METHODS

Phase locked 2 Component-PIV (2C-PIV) measurements were recorded on a typical dissolution apparatus 3 configuration with a black painted tablet fixed at the center of the bottom porous screen of the reciprocating cylinder. A trigger mechanism was employed to capture data over 12 phase positions for each reciprocation cycle. Data were captured over a fixed number of cycles, based on dip rate, and the resultant images were post-processed to obtain phase-averaged velocity fields at each phase.

RESULTS

For all dip rates studied, the sinusoidal nature of the cylinder's reciprocating motion was evident in the images. The phase positions, in which the cylinder was completely submerged, were characterized by recirculation of liquid through the cylinder, top fitting cap, vessel-cylinder annulus, and bottom fitting cap. The direction of recirculation was opposite for phase positions during the up- and downstrokes. The end positions of the up- and downstrokes were characterized by vortices below and above the cylinder respectively. Increasing dip rates led mainly to increasing velocity magnitudes while all flow characteristics, in general, were retained.

CONCLUSIONS

The hydrodynamics in typical USP dissolution apparatus 3 is characterized by cyclic phase-dependent flow fields. Specifically, the velocity field distribution within dissolution apparatus 3 is greatly influenced by the relative position of the top cap to the liquid level in the cylinder.

Links

PMC Free PDF
PMC Free Full Text

Authors+Show Affiliations

Perivilli S
US Pharmacopeial Convention, 12601 Twinbrook Parkway, Rockville, Maryland, 20852-1790, USA. svp@usp.org.
Prevost R
LaVision Inc., 211 W. Michigan Ave./Suite 100, Ypsilanti, Michigan, 48197, USA.
Stippler E
US Pharmacopeial Convention, 12601 Twinbrook Parkway, Rockville, Maryland, 20852-1790, USA.

MeSH

Chemistry, PharmaceuticalHydrodynamicsOptical ImagingParticle SizeRheologySolubilityTablets

Pub Type(s)

Journal Article

Language

eng

PubMed ID

28409325

Citation

Perivilli, Satish, et al. "Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry." Pharmaceutical Research, vol. 34, no. 6, 2017, pp. 1330-1337.
Perivilli S, Prevost R, Stippler E. Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry. Pharm Res. 2017;34(6):1330-1337.
Perivilli, S., Prevost, R., & Stippler, E. (2017). Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry. Pharmaceutical Research, 34(6), 1330-1337. https://doi.org/10.1007/s11095-017-2151-1
Perivilli S, Prevost R, Stippler E. Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry. Pharm Res. 2017;34(6):1330-1337. PubMed PMID: 28409325.
* Article titles in AMA citation format should be in sentence-case
TY - JOUR T1 - Velocity Field Visualization in USP Dissolution Apparatus 3 Using Particle Image Velocimetry. AU - Perivilli,Satish, AU - Prevost,Richard, AU - Stippler,Erika, Y1 - 2017/04/13/ PY - 2017/02/02/received PY - 2017/03/21/accepted PY - 2017/4/15/pubmed PY - 2018/8/9/medline PY - 2017/4/15/entrez KW - USP dissolution apparatus 3 KW - hydrodynamics KW - particle image velocimetry SP - 1330 EP - 1337 JF - Pharmaceutical research JO - Pharm Res VL - 34 IS - 6 N2 - PURPOSE: The hydrodynamics in USP dissolution apparatus 3, at five different dip rates, was characterized by analyzing phase-averaged velocity fields obtained using Particle Image Velocimetry (PIV). METHODS: Phase locked 2 Component-PIV (2C-PIV) measurements were recorded on a typical dissolution apparatus 3 configuration with a black painted tablet fixed at the center of the bottom porous screen of the reciprocating cylinder. A trigger mechanism was employed to capture data over 12 phase positions for each reciprocation cycle. Data were captured over a fixed number of cycles, based on dip rate, and the resultant images were post-processed to obtain phase-averaged velocity fields at each phase. RESULTS: For all dip rates studied, the sinusoidal nature of the cylinder's reciprocating motion was evident in the images. The phase positions, in which the cylinder was completely submerged, were characterized by recirculation of liquid through the cylinder, top fitting cap, vessel-cylinder annulus, and bottom fitting cap. The direction of recirculation was opposite for phase positions during the up- and downstrokes. The end positions of the up- and downstrokes were characterized by vortices below and above the cylinder respectively. Increasing dip rates led mainly to increasing velocity magnitudes while all flow characteristics, in general, were retained. CONCLUSIONS: The hydrodynamics in typical USP dissolution apparatus 3 is characterized by cyclic phase-dependent flow fields. Specifically, the velocity field distribution within dissolution apparatus 3 is greatly influenced by the relative position of the top cap to the liquid level in the cylinder. SN - 1573-904X UR - https://www.unboundmedicine.com/medline/citation/28409325/Velocity_Field_Visualization_in_USP_Dissolution_Apparatus_3_Using_Particle_Image_Velocimetry_ L2 - https://doi.org/10.1007/s11095-017-2151-1 DB - PRIME DP - Unbound Medicine ER -