Abstract
Displacement (D) vs. force (F) profiles obtained during compaction of powders have been reported by several researchers. These profiles are usually used to obtain mechanical energies associated with the compaction of powders. In this work, we obtained displacement–force data associated with the compression of six powders; Avicel PH101, Avicel PH301, pregelatinized corn starch, anhydrous lactose, dicalcium phosphate, and mannitol. The first three powders are known to deform predominantly by plastic behavior while the later ones are known to deform predominantly by brittle fracture. Displacement–force data was utilized to perform in-die Heckel analysis and to calculate the first derivative (dD/dF) of displacement–force plots. First derivative results were then plotted against mean force (F′) at each point and against 1/F′ at compression forces between 1 and 20 kN. Results of the in-die Heckle analysis are in very good agreement with the known deformation behavior of the compressed materials. First derivative plots show that materials that deform predominantly by plastic behavior have first derivative values (0.0006–0.0016 mm/ N) larger than those of brittle materials (0.0004 mm/N). Moreover, when dD/dF is plotted against 1/F′ for each powder, a linear correlation can be obtained (R 2 = > 0.98). The slopes of the dD/dF vs. 1/F′ plots for plastically deforming materials are relatively larger than those for materials that deform by brittle behavior. It is concluded that first derivative plots of displacement–force profiles can be used to determine deformation behavior of powders.
This is a preview of subscription content, log in via an institution to check access.
REFERENCES
De Blaey CJ, Polderman J. Compression of pharmaceuticals. I. The quantitative interpretation of force displacement curves. Pharm Weekblad. 1970;105:241–50.
De Blaey CJ, Polderman J. Compression of pharmaceuticals. II. Registration and determination of force displacement curves. Pharm Weekblad. 1971;106:5765.
De Blaey CJ, Van Oudtshoorn MCB, Polderman J. Compression of pharmaceuticals. III. Study on sulphadimidine. Pharm Weekblad. 1971;106:589–99.
Higuchi T, Arnold RD, Tucker SJ, Busse LW. The physics of tablet compression. I. A preliminary report. J Am Pharm Ass Sci. 1952;41:93–6.
Rasenack N, Müller BW. Crystal habit and tableting behavior. Int J Pharm. 2002;244:45–57.
Heckel RW. Density–pressure relationships in powder compaction. Trans Metall Soc AIME. 1961;221:671–5.
Antikainen O, Yliruusi J. Determining the compression behavior of pharmaceutical powders from the force–distance compression profile. Int J Pharm. 2003;18:253–61.
Ilkka J, Paronen P. Prediction of the compression behavior of powder mixtures by the Heckel equation. Int J Pharm. 1993;94:181–7.
Jetzer WE, Johnson WB, Hiestand EN. Comparison of two different experimental procedures for determining compaction parameters. Int J Pharm. 1986;263:329–37.
Vromans H, De Boer AH, Bolhuis GK, Lerk CF, Kussendrager KD, Bosch H. Studies on tableting properties of lactose part 2 consolidation and compaction of different types of crystalline lactose. Pharm World Sci. 1985;7(5):186–93.
Aburub A, Buckner I, Mishra D. Utilization of compaction energetics for understanding particle deformation mechanism. Pharm Dev Technol. 2007;12:405–14.
Buckner IS, Wurster DE, Aburub A. Interpreting deformation behavior in pharmaceutical materials using multiple consolidation models and compaction energetic. Pharm Dev Technol. 2010;15:492–9.
Author information
Authors and Affiliations
Corresponding author
Rights and permissions
About this article
Cite this article
Gharaibeh, S.F., Aburub, A. Use of First Derivative of Displacement vs. Force Profiles to Determine Deformation Behavior of Compressed Powders. AAPS PharmSciTech 14, 398–401 (2013). https://doi.org/10.1208/s12249-013-9928-2
Received:
Accepted:
Published:
Issue Date:
DOI: https://doi.org/10.1208/s12249-013-9928-2