| 1 |
The effect of roller compaction and tableting stresses on pharmaceutical tablet performance
Rajkumar AD, Reynolds GK, Wilson D, Wren SAC, Salman AD
Powder Technology, 341, 23, 2019 |
| 2 |
Improved micromeritics, packing properties and compressibility of high dose drug, Cycloserine, by spherical crystallization
Kedia K, Wairkar S
Powder Technology, 344, 665, 2019 |
| 3 |
Evaluation of fundamental and functional properties of natural plant product powders for direct compaction based on multivariate statistical analysis
Li Z, Wu F, Zhao LJ, Lin X, Shen L, Feng Y
Advanced Powder Technology, 29(11), 2881, 2018 |
| 4 |
Linking API brittleness in high load formulations to the roller compaction process
Egbu R, Davies C, Dawson N, Coupe A
Powder Technology, 328, 337, 2018 |
| 5 |
Functionality and performance evaluation of directly compressible co-processed excipients based on dynamic compaction analysis and percolation theory
Draskovic M, Djuris J, Ibric S, Parojcic J
Powder Technology, 326, 292, 2018 |
| 6 |
Development of TCM-based composite particles for direct compaction by particle design
Li Z, Xian JC, Wu F, Lin X, Shen L, Feng Y
Powder Technology, 338, 481, 2018 |
| 7 |
Compression and mechanical properties of directly compressible pregelatinized sago starches
Widodo RT, Hassan A
Powder Technology, 269, 15, 2015 |
| 8 |
A methodological approach for determining the effect of moisture content on the compaction properties of powders: Granular hydroxyapatite
Wade JB, Martin GP, Long DF
Powder Technology, 246, 511, 2013 |
| 9 |
A modification of the Pr value equation for measuring the compactibility of pharmaceutical materials
Ilic I, Kasa P, Dreu R, Pintye-Hodi K, Srcic S
Chemical Engineering and Processing, 49(8), 881, 2010 |
| 10 |
Auto-ignition route to thermoelectric oxide NaxCo2O4 powder with high compactibility
Wang WH, Jiang Y, Niu M, Wang LZ, Cao BL
Powder Technology, 184(1), 25, 2008 |
