Abstract
An instrumentation and automation system for a side-vented pan coater with a novel air-flow rate measurement system for monitoring the film-coating process of tablets was designed and tested. The instrumented coating system was tested and validated by film-coating over 20 pilot-scale batches of tablets with aqueous-based hydroxypropyl methylcellulose (HPMC). Thirteen different process parameters were continuously measured and monitored, and the most significant ones were logged for analysis. Laser profilometry was used to measure the surface roughness of the coated tablets. The instrumentation system provided comprehensive and quantitative information on the process parameters monitored. The measured process parameters and the responses of the film-coated tablet batches showed that the coating process is reproducible. The inlet air-flow rate influenced the coating process and the subsequent quality of the coated tablets. Increasing the inlet flow rate accelerated the drying of the tablet surface. At high inlet flow rate, obvious film-coating defects (ie, unacceptable surface roughness of the coated tablets) were observed and the loss of coating material increased. The instrumented and automated pancoating system described, including historical data storage capability and a novel air-flow measurement system, is a useful tool for controlling and characterizing the tablet film-coating process. Monitoring of critical process parameters increases the overall coating process efficiency and predictability.
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References
Cole GC, May G, Neale PJ, Olver MC, Ridgway K. The design and performance of an instrumentation system for aqueous film coating in an industrial tablet coating machine. Drug Dev Ind Pharm. 1983;9(6):909–944.
Le Floc'h JY. Automation of aqueous film coating. Drug Dev Ind Pharm. 1996;22(1):45–50.
Yoakam DA, Campbell RJ. Modeling of a film coating system for computer automation. Pharm Technol. 1984;8(Jan):38–44.
Rantanen J, Känsäkoski M, Suhonen J, Tenhunen J, Lehtonen S, Rajalahti T, Mannermaa J-P, Yliruusi J. Next generation fluidized bed granulator automation. Pharm Sci Tech. 2000; 1 (2) article 10.
UBM Messtechnik GmbH. Microfocus Noncontacting Measurements [brochure], Ettlingen, Germany: UBM Mebtechnik GmbH; 1995.
UBM Messtechnik GmbH. UBM System Reference Guide, UBM Measurement and Analysis Software for Windows, Rev 1.3. Ettlingen, Germany: UBM Mebtechnik GmbH; 1996.
Riippi M, Antikainen O, Niskanen T, Yliruusi J. The effect of compression force on surface structure, crushing strength, friability and disintegration time of erythromycin acistrate tablets. Eur J Pharm Biopharm. 1998;46:339–345.
Okutgen E, Jordan M, Hogan JE, Aulton ME. Effects of tablet core dimensional instability of the generation of internal stresses within film coats. Part II: temperature and relative humidity variation within a tablet bed during aqueous film coating in an accela-cota. Drug Dev Ind Pharm. 1991;17(9):1191–1199.
Franz RM, Doonan GW. Measuring the surface temperature of tablet beds using infrared thermometry. Pharm Technol. 1983;7(Mar):55–67.
Porter SC, Verseput RP, Cunningham CR. Process optimization using design of experiments. Pharm Technol. 1997;21(Oct):60–70.
Schmidt PC, Niemann F. The MiniWid-coater: I. Design and evaluation of a temperature-controlled miniature fluid-bed pan coater. Drug Dev Ind Pharm. 1992;18(17):1907–1919.
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Ruotsalainen, M., Heinämäki, J., Rantanen, J. et al. Development of an automation system for a tablet coater. AAPS PharmSciTech 3, 14 (2002). https://doi.org/10.1208/pt030214
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DOI: https://doi.org/10.1208/pt030214